https://chemwiki.ch.ic.ac.uk/api.php?action=feedcontributions&feedformat=atom&user=Sw4512ChemWiki - User contributions [en]2026-05-15T06:06:42ZUser contributionsMediaWiki 1.43.0https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496338User:Sw4512org2015-03-16T08:14:03Z<p>Sw4512: /* New Candidate for Investigation */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bondings are modeled as springs of various elasticities. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature findings where quantum mechanical transition state calculations performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from Van der Waals and angle bending interactions. The former can be qualitatively reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformations and two new eclipsed conformations are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In a sense there is a gain in staggered interaction in product 2 and no gain in hydrogenation product 1.<br />
Angle bending can be qualitatively explained as in the bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite directions, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
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<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
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<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
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||<jmol><jmolApplet><br />
<title></title><br />
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|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structures with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
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<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
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||<jmol><jmolApplet><br />
<title></title><br />
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<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
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|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, a distorted larger bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
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|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
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<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
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<jmol><jmolApplet><br />
<title></title><br />
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<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
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|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (most of the orange bars are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in most of the blue bars to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation as to where possible parametrisation within the calculation results in this bias. The lack of such information seems to suggest this has not been observed in calculations performed by others.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties, implying they are indeed stereoisomers.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{DOI|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496337User:Sw4512org2015-03-16T08:11:14Z<p>Sw4512: /* Vibrational Circular Dichroism */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bondings are modeled as springs of various elasticities. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature findings where quantum mechanical transition state calculations performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from Van der Waals and angle bending interactions. The former can be qualitatively reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformations and two new eclipsed conformations are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In a sense there is a gain in staggered interaction in product 2 and no gain in hydrogenation product 1.<br />
Angle bending can be qualitatively explained as in the bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite directions, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structures with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, a distorted larger bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (most of the orange bars are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in most of the blue bars to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation as to where possible parametrisation within the calculation results in this bias. The lack of such information seems to suggest this has not been observed in calculations performed by others.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties, implying they are indeed stereoisomers.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496336User:Sw4512org2015-03-16T08:08:24Z<p>Sw4512: /* The calculated NMR properties of products */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bondings are modeled as springs of various elasticities. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature findings where quantum mechanical transition state calculations performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from Van der Waals and angle bending interactions. The former can be qualitatively reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformations and two new eclipsed conformations are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In a sense there is a gain in staggered interaction in product 2 and no gain in hydrogenation product 1.<br />
Angle bending can be qualitatively explained as in the bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite directions, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structures with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, a distorted larger bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (most of the orange bars are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in most of the blue bars to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation as to where possible parametrisation within the calculation results in this bias. The lack of such information seems to suggest this has not been observed in calculations performed by others.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496334User:Sw4512org2015-03-16T08:01:36Z<p>Sw4512: /* Jacobsen Catalyst */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bondings are modeled as springs of various elasticities. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature findings where quantum mechanical transition state calculations performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from Van der Waals and angle bending interactions. The former can be qualitatively reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformations and two new eclipsed conformations are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In a sense there is a gain in staggered interaction in product 2 and no gain in hydrogenation product 1.<br />
Angle bending can be qualitatively explained as in the bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite directions, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structures with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, a distorted larger bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496333User:Sw4512org2015-03-16T07:58:26Z<p>Sw4512: /* Spectroscopic Simulation using Quantum Mechanics */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bondings are modeled as springs of various elasticities. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature findings where quantum mechanical transition state calculations performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from Van der Waals and angle bending interactions. The former can be qualitatively reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformations and two new eclipsed conformations are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In a sense there is a gain in staggered interaction in product 2 and no gain in hydrogenation product 1.<br />
Angle bending can be qualitatively explained as in the bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite directions, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structures with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496332User:Sw4512org2015-03-16T07:54:29Z<p>Sw4512: /* Spectroscopic Simulation using Quantum Mechanics */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bondings are modeled as springs of various elasticities. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature findings where quantum mechanical transition state calculations performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from Van der Waals and angle bending interactions. The former can be qualitatively reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformations and two new eclipsed conformations are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In a sense there is a gain in staggered interaction in product 2 and no gain in hydrogenation product 1.<br />
Angle bending can be qualitatively explained as in the bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite directions, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structures with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496331User:Sw4512org2015-03-16T07:53:48Z<p>Sw4512: /* Spectroscopic Simulation using Quantum Mechanics */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bondings are modeled as springs of various elasticities. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature findings where quantum mechanical transition state calculations performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from Van der Waals and angle bending interactions. The former can be qualitatively reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformations and two new eclipsed conformations are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In a sense there is a gain in staggered interaction in product 2 and no gain in hydrogenation product 1.<br />
Angle bending can be qualitatively explained as in the bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite directions, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structures with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496330User:Sw4512org2015-03-16T07:49:35Z<p>Sw4512: /* Atropisomerism in an Intermediate Related to the Synthesis of Taxol */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bondings are modeled as springs of various elasticities. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature findings where quantum mechanical transition state calculations performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from Van der Waals and angle bending interactions. The former can be qualitatively reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformations and two new eclipsed conformations are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In a sense there is a gain in staggered interaction in product 2 and no gain in hydrogenation product 1.<br />
Angle bending can be qualitatively explained as in the bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite directions, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496329User:Sw4512org2015-03-16T07:42:07Z<p>Sw4512: /* The Hydrogenation of Cyclopentadiene Dimer */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bondings are modeled as springs of various elasticities. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature findings where quantum mechanical transition state calculations performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from Van der Waals and angle bending interactions. The former can be qualitatively reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformations and two new eclipsed conformations are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In a sense there is a gain in staggered interaction in product 2 and no gain in hydrogenation product 1.<br />
Angle bending can be qualitatively explained as in the bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496328User:Sw4512org2015-03-16T07:32:59Z<p>Sw4512: /* Molecular Mechanics */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bondings are modeled as springs of various elasticities. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from the Van der Waals and angle bending interactions. The former can be reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformation and two new eclipsed conformation are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In this very qualitative sense there is a gain in staggered interaction in the hydrogenation product 2 whereas there is not any in hydrogenation product 1.<br />
Angle bending can be explained as in a bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496327User:Sw4512org2015-03-16T07:30:28Z<p>Sw4512: /* Introduction */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational organic chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from the Van der Waals and angle bending interactions. The former can be reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformation and two new eclipsed conformation are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In this very qualitative sense there is a gain in staggered interaction in the hydrogenation product 2 whereas there is not any in hydrogenation product 1.<br />
Angle bending can be explained as in a bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496183User:Sw4512org2015-03-15T22:23:14Z<p>Sw4512: /* The Hydrogenation of Cyclopentadiene Dimer */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
From the energy breakdown, one can see the major difference in energy between the two molecules is from the angle bending energy.<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column four above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column five above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome. The energy breakdown shows the stabilisation for ''hydrogenation product 2'' primarily comes from the Van der Waals and angle bending interactions. The former can be reationalised as after hydrogenation in the bigger ring (hydrogenation product 2) four new staggered conformation and two new eclipsed conformation are established around the vicinity of reaction. While hydrogenation in the smaller ring (hydrogenation product 1) two more staggered and two more eclipsed interactions are established. In this very qualitative sense there is a gain in staggered interaction in the hydrogenation product 2 whereas there is not any in hydrogenation product 1.<br />
Angle bending can be explained as in a bigger ring (hydrogenation product 2), when strain is relieved (by hydrogenation), there are more bonds that can adopt better conformation than there are in a smaller ring.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496181User:Sw4512org2015-03-15T21:43:30Z<p>Sw4512: /* QTAIM */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' drop-down in '''Extension/QTAIM''' (QTAIM stands for Quantum Theory of Atoms in Molecules). Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dashed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP at a position that reflects the relative eletropositivity of the hetroatoms (in C-H bond the yellow point is closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs always resides at the middle (at least qualitatively). <br />
<br />
As there is a point of symmetry in the stilbene reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form the epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496175User:Sw4512org2015-03-15T21:38:52Z<p>Sw4512: /* NCI */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===Non-Covalent Interactions===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls interactions and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state was chosen to be studied. It was mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated, only two types of interactions are present, coded in green and yellow. The former means mild attractive interactions and the latter mildly repulsive interactions. It can be seen the amount (in terms of area) of attractive interactions greatly outweight repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
<br />
The top part of the figure is the catalyst, and the bottom parts of the figure is the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interactions between the fructose rings and the aliphatics of the stilbene very close to the reaction center.<br />
<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496170User:Sw4512org2015-03-15T21:35:17Z<p>Sw4512: /* Transition State Analysis */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S ⇋ R). K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state needs to be selected for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 Kelvin in the calculations.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference was calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here was taken by the R,S-isomer subtracting the S,R-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
It is observed the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition states for such large system sizes at a reasonable computational cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496165User:Sw4512org2015-03-15T21:30:39Z<p>Sw4512: /* Assigning the absolute configuration of the product */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
To obtain the desired data, the stilbene oxides and dihydronaphalene oxides products were first separately conformationally optimised using MMFF94s, then the optical rotation of these epoxide were calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" was included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for a pair of stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature values for an isomeric pair differ in the first digit. This is presumably affected by the limit of measurement accuracy and the extent of isomer purity. <br />
<br />
In terms of the computed values, one can see that firstly the difference in the absolute values between pairs of isomer is larger than the difference in literature values, usually differing in the second digit. This is because each of the isomer was optimised separately using MM and each reached a different local conformational minimum. As the isomers do not have the same conformation (which they do in reality if the solvent is not chiral when subjected to the same physical conditions), their optical rotation value differ by more. <br />
<br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning chirality can be deduced from VCD. For two separate chiral molecules, the VCD spectra should be exact opposite of one another. <br />
<br />
One can see for each pair of isomers, their VCDs are reflections of one another along the horizontal axis. This supports they are indeed stereoisomers. And the presence of the identical IR spectra simply show the two molecules have the same functional groups, which further supports they have the same chemical properties. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496164User:Sw4512org2015-03-15T21:20:31Z<p>Sw4512: /* The calculated NMR properties of products */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation, 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword phrase was used. The solvent was kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. <br />
<br />
Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for the aromatic carbon and protons. This might be due to strong intermolecular π–π stacking in solution phase which alters the electronic properties of the aromatic region. Such intermolecular interaction is not included in single molecular DFT calculation. <br />
<br />
Dihydronaphalene oxides are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectra for both isomers are identical. And the largest deviations come from aromatic carbons and hydrogens.<br />
<br />
An interesting observation from all the NMR calculations performed is the apparent bias for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation. <br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496163User:Sw4512org2015-03-15T21:09:27Z<p>Sw4512: /* Catalyst Strucutrues */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below for ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule is blocked for approach of the reagent.<br />
<br />
The center and rightmost figures show the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups of the pyramid, the distorted bond angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see larger angles for the two bases (104.80° and 100.90°)closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides), again presumably to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituent adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is because of favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening. This shortening is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring, where this acetal group do not have the required geometry to allow the anomeric effect to occur. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl via the planar framework (akin to conjugated alkene system) and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496162User:Sw4512org2015-03-15T21:00:15Z<p>Sw4512: /* Analysis of the Properties of the Synthesised Alkene Epoxides */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties calculations of epoxide products using each of the catalysis schemes are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496161User:Sw4512org2015-03-15T20:48:53Z<p>Sw4512: /* Spectroscopic Simulation using Quantum Mechanics */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. This was done using B3LYP/6-31G(d,p) via Gaussian and adding the keyword phrase ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 as before was adopted and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer. This means if reaction to reach these pair of molecules is again reversible like before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same is true for the boats. This was at first thought to be peculiar, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded when inspecting the connectivity of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change during the DFT calculation. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energies were found to be the same. Consequently, structure with the same free energies produced the same NMR spectra. <br />
<br />
All four conformer share the same labeling order, which is presented below.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
The outcomes of the NMR calculation are tabulated: <br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the tables and the spectra, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 & C10 as well as the S-C-S carbon C3 where there are significant deshielding. While for the proton NMR, the highest chemcial shift signal is the the proton bonded to the alkene, which is the most deshielded proton while all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
<br />
The deviation of calculated C3 value from the literature can be explained because of the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, the deviation can be explained for C7, which is the carbonyl carbon. <br />
<br />
Comparing the carbonyl carbon C9 of the two conformations, one can observe for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale of plots have been set to the same range for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences come from proton environments in the cyclohexane ring, again indicating the NMR sample structure differ the most within the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR analysis was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. Overall, ''down chair 2'' is the most energetically stable atropisomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496156User:Sw4512org2015-03-15T20:30:22Z<p>Sw4512: /* Hyperstable Alkene */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules reacts very slowly which contradicts with theory<ref>J.Bredt, Liebis Ann, 1924, 437 (1), pp. 1-13 {{DOI|10.1002/jlac.19244370102}}</ref>. To investigate this phenomena, optimisation using MMFF94s forcefield is run on the lowest energy ''down chair 2'' structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
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|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
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<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
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|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
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<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
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<title></title><br />
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<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
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|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
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<jmol><jmolApplet><br />
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|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496155User:Sw4512org2015-03-15T20:26:27Z<p>Sw4512: /* Atropisomerism in an Intermediate Related to the Synthesis of Taxol */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. <br />
<br />
An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond are pointing in opposite directions (the two end points from which all the angle measurements are presented in the table), energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. <br />
<br />
It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very locally distorted and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) ''up chair 1'' is actually lower in energy than ''up chair 2''. If there is no significant change locally, then this implies when the aforementioned two groups pointing in the same direction, the reminder parts of the molecule adopts a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, ''down chair 2'' is significantly more stable than ''up chair 1'' (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
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<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496154User:Sw4512org2015-03-15T20:20:31Z<p>Sw4512: /* Atropisomerism in an Intermediate Related to the Synthesis of Taxol */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers (below) of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible (thermodynamic condition), it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be established for ease of reference at later stages. The convention is as follows, if the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this particular atropisomer is said to adopt the ''up'' conformation, while anti-aligned molecule is denoted ''down''. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, resulting in two distinguishable chair conformer and two boat conformers that can assume energy minima. This results in a total of 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered ''1''. Conversely, if this particular carbon is pointing down, then the conforms will be numbered ''2''. To illustrate this naming system, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
<br />
The table below shows the energy contributions for the four different conformer of the ''up'' atropisomer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane, a chair is expected to have a lower energy than boat. But in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted structure, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
The table below shows the energy contributions of the four conformers for the down atropisomer.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements are presented in the table) are pointing in opposite directions, energy of that conformer is lower than if the two groups point in the same direction. This is observed as ''up chair 1'' is lower in energy than ''up chair 2'', while ''down chair 2'' is lower in energy than ''down chair 1''. The same is seen for the boat structures. It was first thought that by enforcing the two groups to point in the same direction, the ring junction is very distorted locally and consequently increases the torsion and bond bending energy. However, one can see from the angle measurements in the table that for both chair and boat 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from the ideal sp<sup>3</sup> 109.5°) up chair 1 is actually lower in energy than up chair 2. If there is significant change locally, then this implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending/torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496153User:Sw4512org2015-03-15T20:06:44Z<p>Sw4512: /* Conformational analysis using Molecular Mechanics */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two products - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref>. This then can be mono-hydrogenated to give again two products, which are arbitrarily denoted ""hydrogenation product 1"" and ""hydrogenation product 2""" (see below). The exo and endo stable intermediates and two final products are studied in sequence using MM.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. <br />
<br />
It is given in the script the endo product is the only product. In order for the higher energy endo molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes the endo transition structure, which is lower in energy than the exo transition structure and reaches the final product. The hypothesised kinetic controlled dimerisation is supported by literature fidnings where quantum mechanical transition state calculation performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower in energy than the exo transition structure.<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496152User:Sw4512org2015-03-15T19:56:28Z<p>Sw4512: /* Introduction */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition states.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead models nuclei and electrons as interacting hard spheres. And chemical bonding model are modeled as springs of various elasticity. The energy is calculated as a sum of contributions from stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way each of these contributing energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (such as equilibrium bond length, bond angle, etc) and proposed equations describing physical phenomena. In this study, the MMFF94s (Merck molecular force field for static processes) is used.<br />
<br />
MM is a very computational cheap way to obtain data when compared to quantum mechanical methods. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and relative contributions from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used.<br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496151User:Sw4512org2015-03-15T19:50:23Z<p>Sw4512: /* Introduction */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, then performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition state.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496150User:Sw4512org2015-03-15T19:47:41Z<p>Sw4512: /* Introduction */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
The aim of this experiment is to develop an appreciation of the capability of computational chemistry by gaining familiarity with different softwares such as performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian, and performing analysis on the results obtained This includes energy comparisons, NMR data rationalisation, study of chiroptical properties of molecules and transition state.Firstly, the two different models used by the softwares- molecular mechanics and quantum mechanical density functional theory- is briefly introduced. <br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496092User:Sw4512org2015-03-15T14:45:30Z<p>Sw4512: /* Transition State Analysis */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess (ee) measures the purity of chiral compounds. It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R (S → R). K for this forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can invoke the relationship between K and the change in free energy:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
ΔG in this case measures the difference between the free energy of the two isomers' transition state. This is why all possible transition states of the alkene with the catalyst need to be found and the lowest energy transition state is chosen for the aforementioned analysis. For the free energies data presented below, the lowest energy is highlighted in green. Temperature was chosen as 293 K in the calculation.<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
One can see the calculated and literature values agree quite well in the case of transition structure of Shi catalyst with stilbenes and of Jacobsen catalyst with dihydronaphthalenes. Additionally the calculated values are systematically larger than literature ones. The difference is mostly due to the computational incapability to accurately determine energy minima of transition state for large system sizes at a reasonable cost.<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496074User:Sw4512org2015-03-15T13:59:32Z<p>Sw4512: /* Vibrational Circular Dichroism */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
In this section, the Vibrational Circular Dichroism (VCD) is presented along with the IR spectrum is presented. VCD provides 3D structural information about a molecule as it can detect the relative orientation of groups in the molecule, meaning it can deduce chirality. For two separate chiral molecule, the VCD should be exact opposite of one another. <br />
For each pair of isomers, the VCD is reflected along the horizontal axis which supports they are indeed isomers. And the presence of the identical IR spectrua simply shows the two molecules have the same functional groups, which further supports they are stereoisomers (same chemical property). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496073User:Sw4512org2015-03-15T13:45:53Z<p>Sw4512: /* Optical Rotation */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
The products were first separately optimised using MMFF94s, then the optical rotation of the epoxide products are calculated quantum mechanically via CAM-B3LYP mehtod with the 6-311++g(2df,p) basis set. the keyword pharse ""polar(optrot) scrf(cpcm,solvent=chloroform) CPHF=RdFreq"" is included in the .com file. The optical rotation was calculated at both 365 nm and 589 nm. Although literature values for 365 nm in chloroform were not found.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -1247.41° ||||-219.78° || -258.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||1235.45° || || 227.17°||256.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
Theoretically, the optical rotation for stereoisomers should have the exact same magnitude, but the opposite signs. However, in reality as one can see the literature value for an isomeric pair differ in the first digit. This is presumably due to the limit of measurement accuracy and the extent of isomer purity. In terms of the computed value, one can see that firstly the difference in the absolute value between pairs of isomer at a given wavelength is larger than the difference in literature value, usually differing in the second digit. This is because each of the isomer is optimised separately using MM and each reached a local minimum. As the isomers do not have the same conformation (which they do in a reality if the solvent is not chiral), their optical rotation value differ by more. <br />
Secondly, comparing computed values to the literature values, the signs agree in all cases. Additionally, as the magnitude of optical rotation is greatly affected by the conformation, the rather small differences (less than 50° in all cases, which is less than 15% of one rotation) is acceptable in the author's opinion.<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496070User:Sw4512org2015-03-15T13:03:12Z<p>Sw4512: /* New Candidate for Investigation */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|cis R-(+)-pulegone oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496069User:Sw4512org2015-03-15T13:02:45Z<p>Sw4512: /* New Candidate for Investigation */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
Cis R-(+)-pulegone oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 7599-91-9 and a molecular weight of 168.236 g/mol. The alkene precursor (R)-(+)-pulegone is readily available in the Sigma Aldrich catalog, with a CAS number of 89-82-7, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in ethanol at 25 °C and 324 nm wavelength light is reported as 853.9°.<ref>William Reusch , Calvin Keith Johnson, J. Org. Chem., 1963, 28 (10), pp 2557–2560 {{DOI|10.1021/jo01045a016.}}</ref><br />
<br />
[[File:candidate_sw4512.PNG|thumb|center|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=File:Candidate_sw4512.PNG&diff=496068File:Candidate sw4512.PNG2015-03-15T12:58:24Z<p>Sw4512: </p>
<hr />
<div></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496067User:Sw4512org2015-03-15T12:35:54Z<p>Sw4512: /* The calculated NMR properties of products */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as before. The solvent is kept as chloroform for which literature values have been attained.<ref name="tetra"></ref><br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|thumb|center|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496066User:Sw4512org2015-03-15T11:53:00Z<p>Sw4512: /* The calculated NMR properties of products */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
The structure of the epoxidation stereoisomers are presented with their NMR properties tabulated. As before, the molecules were first optimised using MMFF94s and then subjected to DFT (B3LYP) calculation and the 6-31G(d,p) basis set with the ""scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"" keyword as beofore.<br />
In determining the plots below, chemical shifts of methyl and methylene protons are again averaged and for literature values with a range, the middle value is taken. Stilbene oxides are presented first:<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
The NMR data obtained are identical for the two isomers. This is expected as stereoisomers should only differ in optical (and biological) properties. However, the deviation between literature and computed value is still quite large, this is especially true for both the aromatic carbon and aromatic protons. It could be that intermolecular π–π stacking interaction is quite strong even in solution phase which alters the electronic properties of the aromatic region. This intermolecular interaction is not included in single molecular DFT calculation. Dihydronaphalene Oxide are presented as follow:<br />
<br />
<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene Oxide !! S,R-1,2-Dihydronapthalene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
Again, the NMR spectrum for both isomer is identical. And the largest deviation comes from the aromatic carbon and hydrogens.<br />
<br />
An interesting trend observed from all the NMR calculation performed is the apparent biase for computed carbon NMR data to be smaller than literature value (all the orange bars in the carbon plots are in the first quadrant) while for the proton NMR the computed values are systematically bigger than literature values, resulting in the blue bars in the proton plots to be in the fourth quadrant. A brief survey of the literature yields no plausible explanation for this.<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|thumb|center|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496065User:Sw4512org2015-03-15T11:09:13Z<p>Sw4512: /* Spectroscopic Simulation using Quantum Mechanics */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
Looking at the table and the spectrum, it makes sense that the highest carbon shifts are for the carbonyl carbon C7, alkene carbon C9 &C10 as well as the S-C-S carbon C3. While for the proton NMR, the highest signal is the the proton bonded to the alkene which is the most deshielded proton whereas all the other proton environments are in the aliphatic region without significant deshielding agent nearby.<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations. One can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be an indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR spectrum was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). In terms of the deviation for the proton NMR, the most pronounced differences comes from the proton environments in the cyclohexane ring, again indicating in NMR sample structure differ the most in the cyclohexane conformation to the computed structures. <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
In determining the graph below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|thumb|center|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496064User:Sw4512org2015-03-15T10:54:10Z<p>Sw4512: /* Spectroscopic Simulation using Quantum Mechanics */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same. Consequently, structure with the same free energy produced the same NMR spectra. <br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:auto; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto; "<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
The two tables above are summarised into the following plots, where the difference between literature values and calculated values are plotted against the atom number.<br />
In determining the results for proton NMR below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
The deviation of C3 can be explained due to the proximity of the heavy sulphur atoms, which causes spin-orbit coupling that leads to calculation error. Similarly, the deviation can be resolved for C21 and C22. The deviations observed for the latter are smaller than for the former. This can be explained because C3 is one bond away from two sulphur atoms, resulting in larger spin-orbit couplings, whereas C21 and C22 only has one sulpur one bond away. Similarly, deviation can be explained for C7, which is the carbonyl carbon. Comparing the carbonyl carbon C9 for the two conformations, one can see that for the boat structure the deviation is the largest amongst all the presented differences. The significant deviation could be a indication that the boat structure used for the calculation is more conformationally varied to the actual sample from which NMR specturm was obtained. This hypothesis is further supported as for both the proton and carbon NMR, the boat conformer shows a generally greater deviation than the chair conformer (the vertical scale has been fixed to be the same for ease of comparison). <br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
In determining the graph below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|thumb|center|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496063User:Sw4512org2015-03-15T10:14:52Z<p>Sw4512: /* Analysis of the Properties of the Synthesised Alkene Epoxides */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
In determining the graph below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
In determining the graph below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|thumb|center|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496062User:Sw4512org2015-03-15T10:13:26Z<p>Sw4512: /* The calculated NMR properties of products */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
In determining the graph below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value<ref name="tetra"></ref> ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
<br />
In determining the graph below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra">M.W.C Robinson, K. S. Pillinger, I. mabbett, D. a.a Timms, A.E. Graham, tetrahedron, 2010 66(43), pp. 8377-8382 {{DOI|10.1016/j.tet.2010.08.078}}</ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value <ref name="tetra"></ref>||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|thumb|center|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496061User:Sw4512org2015-03-15T10:06:03Z<p>Sw4512: /* Spectroscopic Simulation using Quantum Mechanics */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
In determining the graph below, chemical shifts of methyl and methylene protons are averaged and for literature values with a range, the middle value is taken. <br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|thumb|center|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496060User:Sw4512org2015-03-15T09:58:59Z<p>Sw4512: /* Spectroscopic Simulation using Quantum Mechanics */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed by adding the keyword ""opt scrf(cpcm,solvent=chloroform) freq(vcd) NMR EmpiricalDispersion=GD3"". The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|-<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|thumb|center|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496059User:Sw4512org2015-03-15T09:46:47Z<p>Sw4512: /* New Candidate for Investigation */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|-<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|thumb|center|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496058User:Sw4512org2015-03-15T09:45:49Z<p>Sw4512: /* New Candidate for Investigation */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|-<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|thumb|(R)-(+)-α-methylstyrene oxide]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496057User:Sw4512org2015-03-15T09:36:26Z<p>Sw4512: /* The Study of Transition Structures of Pericyclics Reactions */</p>
<hr />
<div>=The Study of Reaction Products Using Molecular Mechanics and the Extraction of Spectroscopic Information via Quantum Mechanics=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|-<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|300px]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496056User:Sw4512org2015-03-14T15:37:30Z<p>Sw4512: /* Shi Catalyst */</p>
<hr />
<div>=The Study of Transition Structures of Pericyclics Reactions=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|-<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
The anomeric effect describes the tendency of a heteroatomic substituents adjacent to a heteroatom to reside in the axial position of a cyclohexane ring. This is due to favourble overlap of bonding and anti-bonding orbitals due to the anti-periplannar orientation. For the Shi catalyst, all the C-O bond length were labeled except the C=O group (C10, O6) and presented below. One can see there is only one six-membered ring, where O2 can exhibit the anomeric effect into O4 through C8, conversely O4 can do the same into O2 again via C8. This better orbital overlap should results in bond shortening, and it is observed where other bonds have a bond length greater than 1.43 Å.<br />
<br />
However, the shortest C-O bond in the system is between O1 and C7 which resides in the five membered ring where the acetal group do not have the required geometry to allow the anomeric effect. Further observation shows that this oxygen is almost in the eclipsed conformation with the carbonyl group. It could be the case that lone pair on O1 can donate its electron density into the carbonyl (like conjugated alkene system) via the planar framework and therefore the charge delocalisation results in bond shortening. <br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|300px]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496055User:Sw4512org2015-03-14T14:58:05Z<p>Sw4512: /* Jacobsen Catalyst */</p>
<hr />
<div>=The Study of Transition Structures of Pericyclics Reactions=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|-<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref>. <br />
Starting with the leftmost figure, one can see many of the hydrogenic interactions at the tert-butyl substituents come very close to double the hydrogen Van der Waals of 2.4 Å, where repusive interaction will begin to dominate. One can also see interactions between the t-butyl and hydrogen on the benzene ring being smaller than 2.4 Å. This can be summarised as high degree of steric hinderance on the left side of the molecule that would prevents the reagent to approach. <br />
<br />
The center and right-most figure shows the bond angles at the square pyramidal metal center, with the chloride (which will be changed to an oxygen in the active species) as the tip. In the center figure, one can see for the four base groups, the bond angle is distorted where an large angle of 90.19° is established between the O-C-O moiety, this is presumably to reduce the repulsive interaction between the t-butyl groups. The rightmost figure measures the angle between the chloride tip and the four bases of the pyramid. One can see a larger angle for the two bases closer to the t-butyl group. This pushes the t-butyl groups further away from the reaction center (where the chloride currently resides) to reduce unfavourable interaction. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|300px]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496054User:Sw4512org2015-03-14T14:38:09Z<p>Sw4512: /* Analysis of the Properties of the Synthesised Alkene Epoxides */</p>
<hr />
<div>=The Study of Transition Structures of Pericyclics Reactions=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|-<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:Jacobesen3 sw4512.PNG|500px]]||[[File:Jacobesen1 sw4512.PNG|500px]]||[[File:Jacobesen2 sw4512.PNG|500px]]<br />
|}<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|300px]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496053User:Sw4512org2015-03-14T14:37:01Z<p>Sw4512: /* Jacobsen Catalyst */</p>
<hr />
<div>=The Study of Transition Structures of Pericyclics Reactions=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|-<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
The Van der Waals radius of hydrogen is 1.2 Å <ref>Batsanov, S. S. "Van der Waals radii of elements." Inorganic materials , 2001: 871-885. {{DOI|10.1023/A:1011625728803}}</ref><br />
[[File:Jacobesen3 sw4512.PNG|left|400px]][[File:Jacobesen1 sw4512.PNG|center|400px]][[File:Jacobesen2 sw4512.PNG|right|400px]]<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
<br />
==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
<br />
[[File:New candidate.PNG|300px]]<br />
<br />
==References==<br />
<references /></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=File:Jacobesen3_sw4512.PNG&diff=496052File:Jacobesen3 sw4512.PNG2015-03-14T14:36:10Z<p>Sw4512: </p>
<hr />
<div></div>Sw4512https://chemwiki.ch.ic.ac.uk/index.php?title=User:Sw4512org&diff=496051User:Sw4512org2015-03-14T14:20:19Z<p>Sw4512: /* Catalyst Strucutrues */</p>
<hr />
<div>=The Study of Transition Structures of Pericyclics Reactions=<br />
==Introduction==<br />
In this experiment,<br />
<br />
performing molecular mechanics calculation via the Avogadro interface and quantum mechanical density functional calculation using Gaussian.<br />
<br />
===Molecular Mechanics===<br />
Molecular Mechanics (MM) is a classical method that neglects all the atomistic details of molecules and instead model nuclei and electrons as interacting hard spheres, with chemical bonding model as springs of various elasticity. The energy is calculated as a sum of contribution of stretching, bending, torsional, Van der Waals and electrostatic energies. The actual way these contribution energy terms are calculated depends on the force field used. The force field is a composition of experimental parameters (for example for equilibrium bond length, bond angle, etc) and proposed physical laws. In this study, the MMFF94s (Merck molecular force field) is used.<br />
<br />
MM is a very computational cheap way to obtain data. But due to the lack of quantum mechanical detail, it is only used to look at relative energy differences between structures to determine relative stability, and the relative contribution of energy from each of the energy terms stated above. Electronic properties are not suitable for investigation using MM.<br />
<br />
===Density Function Theorem===<br />
The density functional theory (DFT) is an ab initio method that models the effect of electronic correlation by focusing on the electron density rather than the wavefunction and uses it to map out the energy. Self-consistently, a guess electronic density is inputted which gets refined after solving the Kohn-Sham equation at each iteration until convergence. In this investigation, the hybrid functional B3LYP formalism is used. Along with the model, a <br />
basis set is needed to construct the overall electron density. The 6-31G(d,p) basis set is used here. <br />
The basis set is constructed using linear combination of atomic orbitals (LCAO), which are Slater type (hydrogenic) orbitals. The Gaussian software approximates these by multiplying Gaussian type orbitals, which reduce computation complexity due to the special property of Gaussian functions which multiply to give another Gaussian (so expensive multiplication can be simplified as adding powers).The naming conventions above means 6 Gaussian orbitals are used to construct the core atomic orbital basis set. While two valence atomic orbital basis sets are needed, with 3 Gaussian orbitals making up the first basis set, and 1 Gaussian orbitals to make up the other. The effect of d-type polarization functions to the basis set is included that in principle better simulate the electronic distribution in molecules.<br />
<br />
Because this quantum mechanical method is closer to atomic reality, it is used to model transition structures, NMR and optical properties as well as molecular electronic topology.<br />
<br />
==Conformational analysis using Molecular Mechanics==<br />
All energy calculations reported are truncated to 5 d.p.<br />
<br />
===The Hydrogenation of Cyclopentadiene Dimer===<br />
The Diels-Alder reaction of cyclopentadienes is a [<sub>π</sub>4<sub>s</sub> + <sub>π</sub>2<sub>s</sub>] process that is capable of producing two product - endo and exo - with the former being the majority product <ref>J. E. BALDWIN, J. Org. Chem., 1966, 31 (8), 2441. {{DOI|10.1021/jo01346a003}}</ref> that can be mono-hydrogenated to give again two products, which are arbitrarily denoted hydrogenation product 1 and 2 (see below). The two stable intermediates and two final products are studied in sequence using MM.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
| [[File:Hydrogenation sw4512.PNG|600px]]<br />
|-<br />
!Reaction Scheme<br />
|}<br />
<br />
Using the MMFF94s forcefield, the two dimerisation products were firstly optimised and are presented below (second and third column). As stated before, the absolute magnitude of the energy reading is not meaningful, instead the relative magnitude is compared. The total energy indicates the exo product is more stable than the endo product. It is given in the script the endo product is the only product. In order for the higher energy molecule to be the product, the reaction needs to be under kinetic control, meaning the dimerisation process irreversibility undergoes an endo transition structure, which is lower in energy than the exo transition structure and reaches the final endo product. The hypothesis that this dimerisation is under kinetic control is further supported by literature data. Transition state structure performed using ab-initio computation methods using various basis sets were performed by Jorgensen et al. showing the endo transition structure is always lower than the exo transition structure in energy.<br />
<ref name="ja00727a021"> William L. Jorgensen , Dongchul Lim , James F. Blake., "Ab initio study of Diels-Alder reactions of cyclopentadiene with ethylene, isoprene, cyclopentadiene, acrylonitrile, and methyl vinyl ketone", J. Am. Chem. Soc., 1993, 115 (7), pp 2936–2942{{DOI|10.1021/ja00727a021}}</ref><br />
<br />
<br />
<br />
<!-- productreactant table --><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
!<br />
!Exo product<br />
!Endo product<br />
!Hydrogenation product 1<br />
!Hydrogenation product 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Exodimer1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>Endodimer2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>150</size><br />
<uploadedFileContents>hp2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 3.54300<br />
| 3.46743<br />
| 3.30837<br />
| 2.82311<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 30.77270<br />
| 33.19066<br />
| 30.86465<br />
| 24.68517<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -2.04139<br />
| -2.08218<br />
| -1.92668<br />
| -1.65717<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| -2.73102<br />
| -2.94975<br />
| 0.05894<br />
| -0.37828<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.01485<br />
| 0.02197<br />
| 0.01536<br />
| 0.00028<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 12.80162<br />
| 12.35784<br />
| 13.28120<br />
| 10.63735<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 13.01367<br />
| 14.18472<br />
| 5.12099<br />
| 5.14702<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 55.37344<br />
| 58.19069<br />
| 50.07228<br />
| 41.25749<br />
<br />
|}<br />
<!-- productreactant table --><br />
<br />
Using the same optimisation method, the endo product is subjected to hydrogenation at one of the two double bond site. The product with cyclo-pentene hydrogenated is denoted '''hydrogenation product 1''' (column three above) while the one with norbornene double bond hydrogenated is denoted '''hydrogenation product 2''' (column four above). <br />
<br />
Experimental hydrogenation catalysed by SRNA-4 nickel alloy <ref name="ja00727a0"> Ji-Jun Zou, Xiangwen Zhang, Jing Kong, Li Wang (2008). "Hydrogenation of Dicyclopentadiene over amorphous nickel alloy catalyst SRNA-4". Fuel 87: 3655–3659. doi: 10.1016/j.fuel.2008.07.006{{DOI|10.1016/j.fuel.2008.07.006}}</ref> indicates the '''hydrogenation product 2''' is easier to hydrogenate. As it is also lower in energy, this implies the reaction is under thermodynamic control, where crossing of the transition state is reversible and results in the most energetically stable product as the majority outcome.<br />
<br />
===Atropisomerism in an Intermediate Related to the Synthesis of Taxol===<br />
Upon a multi-step synthesis of Taxol <ref>S. W. Elmore and L. Paquette, Tetrahedron Letters, 1991, 319; {{DOI|10.1016/S0040-4039(00)92617-0}}</ref>, a intermediate (below) during the synthesis is isolated. Due to rotational strain it is possible to obtain two atropisomers of this intermediate. As it has been discovered<ref> S. W. Elmore and L. Paquette, Tetrahedron Lett., 1991, 32 (3), 319. {{DOI|10.1016/S0040-4039(00)92617-0}}</ref> that the reaction to reach this intermediate is reversible, it is important to determine the lower energy isomer which will in turn be the major product. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Atropisomer.PNG|400px]]<br />
|-<br />
!Atropisomers of an intermediate during Taxol synthesis<br />
|}<br />
Before investigation on the intermediate can be undertaken, a naming convention needs to be deviced for the ease of reference at any later stage. The convention is as below. If the dipole of the carbonyl group is aligned in the same direction as the bridging methyl group within the eight-membered ring, then this atropisomer is said to adopt the ''up'' conformation. For each of the atropisomers, there are substituents unsymmetrically distributed around the cyclohexane ring, there are two distinguishable chair conformer and two boat conformers that can assume energy minima on the potential energy surface. This results in 8 different structures needing analysis. To further distinguish the two chairs and two boats that will form for each atropisomer, it is decided when the carbon (circled in green below) in the cyclohexane ring that is closer to the alkene functionality is pointing in the upward direction (again up is relative to the bridging methyl group), the consequent chair or boat conformer will be numbered 1. Conversely, if this particular carbon is pointing down, then the conforms will be numbered 2. As examples, the structure below on the left is ''up chair 1'', while the one on the right is ''down boat 2''<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
![[File:9_chair1_sw4512.PNG |500px]] !! [[File:10 boat2 sw4512.PNG |500px]] <br />
|-<br />
!up chair 1 !! down boat 2<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate A (up)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><script>measure 6 1 7; </script><br />
<size>200</size><br />
<uploadedFileContents>Up_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.94775<br />
| 8.00244<br />
| 7.67267<br />
| 8.22775<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 29.69565<br />
| 30.22872<br />
| 28.26759<br />
| 34.04495<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.09941<br />
| -0.03609<br />
| -0.07766<br />
| 0.07349<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 2.61550<br />
| 2.68599<br />
| 0.23951<br />
| 3.64864<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.95378<br />
| 0.95719<br />
| 0.98600<br />
| 1.66122<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.66062<br />
| 35.80138<br />
| 33.15496<br />
<br />
| 34.78910<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.31868<br />
| 0.22920<br />
| 0.29743<br />
| 0.19973<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 76.29140<br />
| 77.93162<br />
| 70.54050<br />
| 82.64489<br />
<br />
|}<br />
<br />
<br><br />
For the up structure, the lowest energy conformer is chair 1. Looking into the specifics of the energy distribution, the low energy content is mostly due to the angle bending energy and the torsion energy comparing to the other three structures. Although for cyclyhexane chair are expected to have a lower energy than boat, in this case the chair 2 structure has the highest energy content out of the four conformers. This can be partly explained as the boats optimised actually assumes a slightly twisted boat strucutre, which lowers their respective energy contents. Additionally, chair 2 has by far the largest angle bending and out-of-plane bending energy, meaning high strain is suffered to assume this structure. <br />
---------------------------------------<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan='5' | Intermediate B (down)<br />
|-<br />
!<br />
!Twisted Boat 1<br />
!Twisted Boat 2<br />
!Chair 1<br />
!Chair 2<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat1_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair1 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<script>measure 6 1 7; </script><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 7.79383<br />
| 7.75327<br />
| 8.66163<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 21.24496<br />
| 19.02340<br />
| 21.82979<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| -0.05966<br />
| -0.13238<br />
| -0.19520<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 4.44638<br />
| 3.75328<br />
| 6.14934<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.93208<br />
| 0.95053<br />
| 1.63871<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 34.56384<br />
| 35.00274<br />
| 36.22957<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| -0.04521<br />
| -0.06235<br />
| 0.41927<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 68.87622<br />
| 66.28850<br />
| 74.73312<br />
| 60.55042<br />
|}<br />
For the down structure, the lowest energy conformer is changed from chair 2 to chair 1, the former now assumes the highest energy. Again, torsion energy and angle bending energy seems to play important roles. Additionally Van der Waals seems to play a important role as well. An interesting pattern is observed. When the cyclohexane end closer to the carbonyl group and the C=O bond (the two end points from which all the angle measurements presented above) are pointing in opposite directions, energy of the conformer is lower than if the two groups point in the same direction. This is observed as up chair 1 is lower in energy than up chair 2, while down chair 2 is lower in energy than down chair 1. The same is seen for the boat structures. It was first thought that by enforcing the two groups two point in the same direction, the ring junction is very distorted locally and consequently increase the torsion and bond bending energy. However, one can see from the angle measurements that for all pairs of 1&2 structures the angle is roughly the same. In the case of the up chairs, the more distorted (away from 109.5°) up chair 1 is actually lower in energy than up chair 2. This implies the aforementioned two groups pointing in the same direction leads to the reminder molecule adopting a more strained form and perhaps small amounts of bond bending and torsion accumulates within the eight-membered ring and causes a raise in overall energy.<br />
<br />
Comparing the lowest energy structure from up and down, down chair 2 is significantly more stable than up chair 1 (by about 10 kcal/mol). This difference can almost exclusively be accounted for by the angle bending energy. As in this case both structures have the carbonyl and cyclohexane carbon defined above pointing in opposite direction, this implies the relative orientation of the methylene group in the oct-member ring and carbonyl group is important.<br />
<br />
===Hyperstable Alkene===<br />
It is stated in the script that the alkene functional group from the above molecules react very slowly which contradicts with theory. To investigate this phenomena optimisation using MMFF94s forcefield is run on the lowest energy down chair 2 structure (denoted alkene) and its hydrogenated version (denoted alkane below). <br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|-<br />
!<br />
!Alkane<br />
!Alkene<br />
<br />
|- align="center"<br />
!Jmol<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Hyperstable alkane sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>400</size><br />
<uploadedFileContents>Down_chair2_sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
<br />
|- align="center"<br />
!Total Bond Stretching Energy (kcal/mol)<br />
| 6.42175<br />
| 7.58865<br />
<br />
<br />
|- align="center"<br />
!Total Angle Bending Energy (kcal/mol)<br />
| 22.28351<br />
| 18.81421<br />
<br />
<br />
|- align="center"<br />
!Total Stretch-bending Energy (kcal/mol)<br />
| 0.29379<br />
| -0.14175<br />
<br />
<br />
|- align="center"<br />
!Total Torsion Energy (kcal/mol)<br />
| 9.20418<br />
| 0.23156<br />
<br />
<br />
|- align="center"<br />
!Total Out-of-plane Bending Energy (kcal/mol)<br />
| 0.03894<br />
| 0.84317<br />
<br />
|- align="center"<br />
!Total Van der Waals Energy (kcal/mol)<br />
| 31.29324<br />
| 33.26869<br />
<br />
<br />
|- align="center"<br />
!Total Electrostatic Energy (kcal/mol)<br />
| 0.00000<br />
| -0.05411<br />
<br />
<br />
|- align="center"<br />
!Total Energy (kcal/mol)<br />
| 69.53538<br />
| 60.55042<br />
<br />
|}<br />
The relative energies of both structure shows that hydrogenation is thermodynamically unfavoured by almost 10 kcal/mol. The alkene is favoured primarily due to small torsion energy and angle bending energy. This hyperstability of ring junction alkene is supported by the work of Maier et al <ref>Wilhelm F. Maier, Paul Von Rague Schleyer (1981). "Evaluation and prediction of the stability of bridgehead olefins". J. Am. Chem. Soc. 103(8): 1891–1900. {{DOI|10.1021/ja00398a003}}</ref>.<br />
<br />
==Spectroscopic Simulation using Quantum Mechanics==<br />
In this part of the study, using B3LYP/6-31G(d,p) via Gaussian, the carbon and hydrogen NMRs of a thiol derivative of the intermediates studied above was computed. The same convention for up and down as well as 1 and 2 is adopted as before and the '''up''' isomer is arbitrarily chosen for the NMR study. Even though it was later found the down isomer actually contains the lowest energy conformer, and if reaction to reach these pair of molecules is again reversible as before, it would be more meaningful to investigate the down isomer instead.<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
| [[File:Nmr sw4512.PNG|400px]]<br />
|-<br />
! Derivatives of the Taxol intermediate studied above<br />
|}<br />
The solvent is kept as chloroform, for which both carbon and hydrogen NMR literature data is attained <ref name="nmr"> Leo A. Paquette, et al. (1981). "[3.3] Sigmatropy within 1-vinyl-2-alkenyl-7,7-dimethyl-exo-norbornan-2-ols. The first atropselective oxyanionic Cope rearrangement". J. Am. Chem. Soc. 112(1): 277–283. {{DOI|10.1021/ja00157a043}}</ref><br />
<br />
Each of the structure was drawn in ChemBio3D and imported into Avogadro and subjected to optimisation using MMFF94s force field (see the ''Total Energy from MM'' row below). The optimised structures were then submitted to the high performance cluster for quantum mechanical calculations. For Gaussian calculations where the energy is requested, the unit is converted from Hatrees to kcal/mol (see the ''Free Energy from DFT'' row below).<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Up <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 (twisted) !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 chair2 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr17 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 104.78692 !! 118.01969 !! 125.56113 !!120.36236<br />
|-<br />
!DOI || {{DOI|10042/195235}} || {{DOI|10042/195236}} ||{{DOI|10042/195246}} ||{{DOI|10042/195247}}<br />
<br />
|-<br />
|-1651.461190<br />
|-<br />
|<math>^1H </math>NMR || [[File:17 chair1 h sw4512.PNG|400px]] ||[[File:17 chair2 h sw4512.PNG|400px]] ||[[File:17 boat1 h sw4512.PNG|400px]] ||[[File:17 boat2 h sw4512.PNG|400px]]<br />
|-<br />
| <math>^{13} C </math>NMR || [[File:17 chair1 c sw4512.PNG|400px]] ||[[File:17 chair2 c sw4512.PNG|400px]] ||[[File:17 boat1 c sw4512.PNG|400px]] ||[[File:17 boat2 c sw4512.PNG|400px]]<br />
|-<br />
!Free Energy from DFT(kcal/mol) || -1036307.76401 || -1036307.76401 || -1036293.22461 || -1036293.22461<br />
|-<br />
|}<br />
It is observed that for the free energy obtained for the two chairs are identical, the same occurred for the boats. This was thought to be rather peculiar that conformational isomers would have exact energies, because the potential energy surface for a molecule of such size and complexity should not be so regular (put it in another way, these identical energies obtained suggests a degree of symmetry in the potential energy surface that is unfounded in the geometry of the molecule). However, it was later realised that the MM optimised conformers underwent conformational change. In each case, the lower (MM calculated) energy conformer in the chair & boat pair was reached during the DFT calculation and its NMR was generated. Thus the free energy were found to be the same.<br />
<br />
For the detailed studies of NMR below, the numbers labels below corresponds to those in the '''Atoms''' column.<br />
[[File:17_labeled_sw4512.PNG||center||650px]]<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| <sup>13</sup>C NMR Chemical Shift Results (ppm)<br />
|-<br />
! Atom !!Chair !!Boat !! !!Literature<ref name="nmr"></ref><br />
|-<br />
|7||206.398 ||204.758 || ||218.79<br />
|-<br />
|10 || 135.424 ||139.673 ||||144.63 <br />
|-<br />
|9 || 114.988 ||107.209 || ||125.33 <br />
|-<br />
|3|| 80.943 ||81.565 || ||72.88 <br />
|-<br />
|2 || 50.935 ||54.849 || ||56.19 <br />
|-<br />
|1 || 47.341 ||50.624 || ||52.52 <br />
|-<br />
|15 || 42.773 ||44.311 || ||48.50 <br />
|-<br />
|13 || 41.842 ||43.148 || || 46.80 <br />
|-<br />
|21 || 36.990 || 37.928 || || 45.76 <br />
|-<br />
|14 || 36.247 || 36.925 || || 39.80 <br />
|-<br />
|22 || 32.468 || 34.486 || || 38.81 <br />
|-<br />
|4 || 30.870 ||30.362 || || 35.85 <br />
|-<br />
|6 || 25.616 || 23.470 || || 32.66 <br />
|-<br />
|8 ||21.306|| 23.166 || || 28.79 <br />
|-<br />
|12 ||19.633 || 21.755 || || 28.29 <br />
|-<br />
|23 || 19.633 || 20.981 || || 26.88 <br />
|-<br />
|11 || 17.389 || 17.658 || ||25.66 <br />
|-<br />
|17 || 16.698 || 17.163 || || 23.86 <br />
|-<br />
|5 || 13.199 || 12.352 || || 20.96 <br />
|-<br />
|16 || 10.022 || 11.860 || || 18.71<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="2"| boat !! rowspan="2"|Literature Value(ppm)<ref name="nmr"></ref>!!colspan="2"| chair <br />
|-<br />
!Atoms!! Shift (ppm) !!Atoms !!Shift (ppm)<br />
<br />
|-<br />
| 33 || 5.669 || 4.84|| 33 || 5.286<br />
|-<br />
| 47 || 3.585 ||rowspan="4"| 3.40-3.10|| 50 || 3.443 <br />
|-<br />
| 48 || 3.502 || 49 || 3.356<br />
|-<br />
| 50 || rowspan="2" |3.413 || 24 || 3.294 <br />
|-<br />
| 31 || 48 || rowspan="2" |3.150<br />
|-<br />
| 49 || rowspan="2" |3.123|| 2.99 || 47 <br />
|-<br />
| 32 || rowspan="14"|2.80-1.35|| 34 || rowspan="2" |2.851<br />
|-<br />
| 34 || 2.979 || 31 <br />
|-<br />
| 24 || 2.815 || 43 || 2.770<br />
|-<br />
| 38 || 2.483 || 40 || rowspan="4" |2.532<br />
|-<br />
| 35 || rowspan="4" |2.389 || 39 <br />
|-<br />
| 26 || 32 <br />
|-<br />
| 25 || 26 <br />
|-<br />
| 40 || 36 || rowspan="2" |2.409<br />
|-<br />
| 36 || 2.101106945 || 35 <br />
|-<br />
| 39 || rowspan="2" |2.023 || 38 || rowspan="2" |2.257<br />
|-<br />
| 27 || 30 <br />
|-<br />
| 28 || 1.942|| 25 || 2.090<br />
|-<br />
| 30 || 1.851|| 28 || 2.039 <br />
|-<br />
| 43 || 1.711 || 52 || 1.881<br />
|-<br />
| 44 || 1.653 || rowspan="3"|1.38|| 44 || rowspan="3" |1.731<br />
|-<br />
| 51 || 1.382|| 37 <br />
|-<br />
| 53 || 1.330|| 27 <br />
|-<br />
| 46 || rowspan="2" |1.189 || rowspan="3"|1.25|| 29 || 1.625<br />
|-<br />
| 37 || 51 || 1.300 <br />
|-<br />
| 52 || 1.103 || 46 || rowspan="3" |1.043 <br />
|-<br />
| 41 || rowspan="2" |1.012882963||rowspan="3"| 1.1 || 45 <br />
|-<br />
| 29 || 42 <br />
|-<br />
| 45 || 0.849 || 41 || 0.959 <br />
|-<br />
| 42 || 0.705 || 1.00-0.80|| 53 || 0.727<br />
|-<br />
|}<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
|[[File:17 chair nmr c sw4512.PNG|600px]] ||[[File:17 boat nmr c sw4512.PNG|600px]]<br />
|-<br />
|[[File:17 chair nmr h sw4512.PNG|600px]] ||[[File:17 boat nmr h sw4512.PNG|600px]]<br />
|}<br />
<br />
<br />
<br />
The down isomer was also optimised and submitted for NMR calculation. The free energy generated are presented below, but due to time constraint detailed NMR calculation was not performed on it. One can see the free energy for chair 1, boat 1 and boat 2 are the same, suggesting conformational change had occurred, most probably all three changed to the lowest energy boat 2 conformer. <br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5"| Down <br />
|-<br />
!Conformer !! Chair 1!! Chair 2 !! Boat 1 !! Boat 2<br />
|-<br />
|Jmol <br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair1 sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet> <br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 chair2 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat1 sw4512.mol </uploadedFileContents> <br />
</jmolApplet></jmol><br />
||<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>300</size><br />
<uploadedFileContents>Nmr18 boat2 sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
!Total Energy from MM (kcal/mol) !! 105.55504 !!100.43765 !! 102.31498 !!102.22221<br />
|-<br />
!DOI || {{DOI|10042/195244}} || {{DOI|10042/195241}} ||{{DOI|10042/195245}} ||{{DOI|10042/195243}}<br />
|-<br />
!Free Energy from DFT (kcal/mol) || -1036307.48352|| -1036309.64905||-1036307.48352 || -1036307.48352<br />
|}<br />
<br />
==Analysis of the Properties of the Synthesised Alkene Epoxides ==<br />
Two asymmetric catalysts are studied in this section. The Jacobsen catalyst, published in 1991 for asymmetric epoxidation of alkenes <ref>W. Zhang, E. N. Jacobsen, J. Org. Chem., 1991, 56 (7), 2296. {{DOI| 10.1021/jo00007a012}}</ref> and the Shi catalyst also for asymmetric epoxidation of trans-alkenes and tri-substituted olefins discovered in 1996 <ref>Tu, Y.; Wang, Z.-X.; Shi, Y. J. Am. Chem. Soc. 1996, 118, 9806-9807. {{DOI|10.1021/ja962345g}}</ref>.<br />
The structure of the salen catalysts (precursors to the active species) are studied first, following which the NMR and optical properties of epoxide products using each of the catalysis scheme are conducted. The study culminates with energetic and electronic analysis of the epoxidation transition states. <br />
<br />
===Catalyst Strucutrues===<br />
The salen species for the Shi catalyst was found on the PubChem Compound Database. The compound (formal name: 1,2:4,5-Di-O-isopropylidene-beta-D-erythro-2,3-hexodiulo-2,6-pyranose) has a CID: 18422-53-2. <br />
While the salen precursor to Jacobsen catalyst was found on the ConQuest Database using the molecular formula C<sub>36</sub>H<sub>52</sub>ClMnN<sub>2</sub>O<sub>2</sub>. The TOVNIB01 structure was chosen for further investigation. Both compound was visualised using the program Mercury. In the case of Jacobsen catalyst, one unit of the catalyst was deleted, leaving only one unit for the analysis below due to the ease of visualisation. <br />
<br />
====Jacobsen Catalyst====<br />
<br />
[[File:Jacobesen1 sw4512.PNG|left|600px]][[File:Jacobesen2 sw4512.PNG|center|600px]]<br />
<br />
<br><br />
<br />
====Shi Catalyst====<br />
[[File:shi sw4512.PNG|center|800px]]<br />
<br />
===The calculated NMR properties of products===<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
<br />
|-<br />
! S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SSstilbene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RRstilbene sw4512.mol</uploadedFileContents> <br />
</jmolApplet></jmol><br />
|-<br />
|[[File:SSstilbene labeled sw4512.PNG|400px]] || [[File:RRstilbene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195240}} || {{DOI|10042/195239}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:SSstilbene h sw4512.PNG|400px]] ||[[File:RRstilbene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:SSstilbene c sw4512.PNG|400px]] ||[[File:RRstilbene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='15'| [[File:Stilibene nmr c sw4512.PNG]]<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 124.382 || 137.7<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 114.515 || 129.1<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.813 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.508 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 113.374 || 128.8<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 108.559 || 126.1<br />
|-<br />
| 56.72 || 63.3<br />
|-<br />
| 56.72 || 63.3<br />
|}<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='13'| [[File:Stilibene nmr h sw4512.PNG]]<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.706 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 7.615 || 7.42–7.52<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
| 3.673 || 3.98<br />
|-<br />
|}<br />
<br><br />
<br />
<br />
<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R,S-1,2-Dihydronapthalene !! S,R-1,2-Dihydronapthalene<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>RS12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || <br />
<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>SR12dihydronapthalene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
|[[File:RS12dihydronapthalene labeled sw4512.PNG|400px]] || [[File:SR12dihydronapthalene labeled sw4512.PNG|400px]]<br />
|-<br />
| {{DOI|10042/195237}} || {{DOI|10042/195238}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene h sw4512.PNG|400px]] || [[File:SR12dihydronapthalene h sw4512.PNG|400px]]<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
|[[File:RS12dihydronapthalene c sw4512.PNG|400px]] || [[File:SR12dihydronapthalene c sw4512.PNG|400px]]<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr c sw4512.PNG]]<br />
|-<br />
| 124.1373 || 137.1<br />
|-<br />
| 120.679 || 132.9<br />
|-<br />
| 115.848 || 129.9<br />
|-<br />
| 114.1308 || 129.8<br />
|-<br />
| 113.7204 || 128.8<br />
|-<br />
| 111.7367 || 126.5<br />
|-<br />
| 46.729 || 55.5<br />
|-<br />
| 45.12417 || 53.2<br />
|-<br />
| 18.33161 || 24.8<br />
|-<br />
| 15.24076 || 22.2<br />
|-<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!Calcualted Value !! Literature Value ||rowspan='11'| [[File:SR12dihydronapthalene nmr h sw4512.PNG]]<br />
|-<br />
| 7.626236627 || 7.45<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.522080147 || 7.35–7.20<br />
|-<br />
| 7.331131433 || 7.15<br />
|-<br />
| 3.723632408 || 3.90<br />
|-<br />
| 3.723632408 || 3.77<br />
|-<br />
| 3.01604874 || 2.85–2.80<br />
|-<br />
| 2.403607563 || 2.60–2.55<br />
|-<br />
| 2.352149306 || 2.50–2.40<br />
|-<br />
| 1.698658613 || 1.80–1.75<br />
|-<br />
|}<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
! R-Styrene Oxide !! S-Styrene Oxide<br />
|-<br />
|<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Rstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol> || |<jmol><jmolApplet><br />
<title></title><br />
<color>lightgrey</color><br />
<size>200</size><br />
<uploadedFileContents>Sstyrene sw4512.mol</uploadedFileContents><br />
</jmolApplet></jmol><br />
|-<br />
| {{DOI|10042/195252}} || {{DOI|10042/195251}} <br />
|-<br />
!colspan="2"| <math>^1H </math>NMR <br />
|-<br />
| ||<br />
|-<br />
!colspan="2"| <math>^{13} C </math>NMR <br />
|-<br />
| ||<br />
|}<br />
<br />
<br />
<br/><br />
<br />
===Assigning the absolute configuration of the product===<br />
<br />
====Optical Rotation====<br />
<br />
Literature value for 365 nm are not found. The signs are supported.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4" | S,S-Stilbene Oxide!! colspan="4" |R,R-Stilbene Oxide<br />
|-<br />
|colspan="4" | {{DOI|10042/195332}} || colspan="4" |{{DOI|10042/195329}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -7.41° ||||-19.78° || -358.1°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref>||35.45° || || 27.17°||356.1 °<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="5" |R,S-1,2-Dihydronapthalene !!colspan="5" |S,R-1,2-Dihydronapthalene<br />
|-<br />
|colspan="4" | {{DOI|10042/195326}} || colspan="4" |{{DOI|10042/195325}} <br />
|-<br />
!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm !!Computed value at 365 nm !! !!Computed value at 589 nm !! Literature value at 589 nm<br />
|-<br />
| -633.86° || ||-183.16° || -138.8°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref> ||631.78° || ||182.63°|| 135.3°<ref name="ja"> Z. Wang,Y. Tu,M. Frohn,J. Zhang and Y. Shi Journal of the American Chemical Society 1997 119 (46), 11224-11235. {{DOI|10.1021/ja972272g}}</ref><br />
|}<br />
<br />
====Vibrational Circular Dichroism====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!S,S-Stilbene Oxide!! R,R-Stilbene Oxide<br />
|-<br />
| {{DOI|10042/195330}} || {{DOI|10042/195331}} <br />
|-<br />
|[[File:SSstilbene vcd sw4512.PNG|400px]] || |[[File:RRstilbene vcd sw4512.PNG|400px]] <br />
|}<br />
<br />
<br><br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!R,S-1,2-Dihydronapthalene !!S,R-1,2-Dihydronapthalene<br />
|-<br />
| {{DOI|10042/195328}} || {{DOI|10042/195327}} <br />
|-<br />
| [[File:RS12dihydronapthalene vcd sw4512.PNG|400px]] || [[File:SR12dihydronapthalene vcd sw4512.PNG|400px]]<br />
|}<br />
<br />
<br />
<br />
===Transition State Analysis===<br />
The enantiomeric excess <br />
<br />
It is mathematically defined as:<br />
<br />
<math>\ ee = ((R-S)/(R+S)) </math> <br />
<br />
where R and S are the relative fraction of each of the two enantiomer. The relative fractions of R and S can be obtained from the equilibrium constant K for the interconversion between S and R. K for the forward reaction is as below:<br />
<br />
<math> K = R / S</math><br />
<br />
Substituting the above relation to the ee equation one can obtain the following:<br />
<br />
<math> ee = |1-K / 1+K|</math><br />
<br />
To obtain K, one can utilise the free energies for both enantiomers provided by the Gaussian calculation and work out the difference:<br />
<br />
Δ<Math>G = - RTln(K)</math><br />
<br />
<br />
====Transition Structure of Shi Catalyst with Stilbenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.828552}} ||-963031.34484|| {{DOI|10.6084/m9.figshare.829524}}||-963028.60388<br />
|-<br />
| {{DOI|10.6084/m9.figshare.830388}} ||-963030.99595|| {{DOI|10.6084/m9.figshare.829525}}||-963029.63864<br />
|-<br />
| {{DOI|10.6084/m9.figshare.829522}} ||<span style="color:green"> -963039.01866 </span>|| {{DOI|10.6084/m9.figshare.830389}}||<span style="color:green">-963035.11618</span><br />
|-<br />
| {{DOI|10.6084/m9.figshare.829523}} ||-963038.93332|| {{DOI|10.6084/m9.figshare.830390}}||-963033.88626<br />
|}<br />
<br />
The energy units were converted to J/mol before proceeding with calculating the value of K and the ee value that is to follow. The difference is calculated by doing the R-isomer subtracting the S-isomer.<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| -16327.97632||814.36234||99.8||83<ref>Yian Shi, et al. (2009). "Asymmetric Epoxidation Catalyzed by α,α-Dimethylmorpholinone Ketone. Methyl Group Effect on Spiro and Planar Transition States". J. Org. Chem. 74(16): 6335–6338. {{DOI|10.1021/jo900739q}}</ref><br />
|}<br />
<br><br />
<br />
====Transition Structure of Shi Catalyst with Dihydronaphthalenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Shi epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.832492}} ||-866666.56055|| {{DOI|10.6084/m9.figshare.832538}}|| -866673.185802<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832510}} ||-866669.76336|| {{DOI|10.6084/m9.figshare.832536}}|| -866663.622556<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832511}} ||<span style="color:green">-866674.89200</span>|| {{DOI|10.6084/m9.figshare.832545}}|| -866669.853726<br />
|-<br />
| {{DOI|10.6084/m9.figshare.832512}} ||-866670.28796|| {{DOI|10.6084/m9.figshare.832544}}|| <span style="color:green">-866676.254324</span><br />
|}<br />
Energy difference here is taken by the R,S-isomer subtracting the S,R-isomer<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
|5699.96362||0.09635||82.4||32 <ref>M. Frohn, Y. Shi, Synthesis, 2000, 14, 1979-2000</ref><br />
|}<br />
<br />
====Transition Structure of Jacobsen Catalyst with Stilbenes====<br />
<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Stilbene<br />
|-<br />
!colspan="2"| R,R series !!colspan="2"| S,S Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
|-<br />
| {{DOI|10.6084/m9.figshare.899176}} ||<span style="color:green">-2243297.38463</span>||{{DOI|10.6084/m9.figshare.903625}}||<span style="color:green">-2243298.58506</span><br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 5022.59912||0.12724||77.4 ||25<ref>Paola Piaggio, et al. (2000). "Enantioselective epoxidation of (Z)-stilbene using a chiral Mn(III)–salen complex: effect of immobilisation on MCM-41 on product selectivity". J. Chem. Soc., Perkin Trans. 2, missing volume(10): 2008-2015.{{DOI|10.1039/B005752P}}</ref><br />
<br />
|}<br />
<br />
<br><br />
<br />
====Transition Structure of Jacobsen Catalyst with Dihydronaphthalenes====<br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!colspan="4"| Transition states for Jacobsen epoxidation of Dihydronaphthalene<br />
|-<br />
!colspan="2"| R,S series !!colspan="2"| S,R Series<br />
|-<br />
! DOI !! Free Energy (kcal/mol) !! DOI !! Free Energy (kcal/mol) <br />
<br />
|-<br />
| {{DOI|10.6084/m9.figshare.909346}} ||-2146935.86716|| {{DOI|10.6084/m9.figshare.903752}} ||<span style="color:green">-2146941.94082</span><br />
|-<br />
|{{DOI|10.6084/m9.figshare.907332}} ||<span style="color:green">-2146935.958149</span>|| {{DOI|10.6084/m9.figshare.907473}} ||-2146937.26399<br />
|}<br />
<br><br />
{| class="wikitable" style="text-align:center; margin: auto;"<br />
!ΔG (J/mole) !! K !! Calculated ee(%) !! Literature ee(%)<br />
|-<br />
| 25031.49546||3e-05||100.0 || 85<ref>J. Hanson, J. Chem. Educ., 2001, 78(9), 1266-1268, {{DOI|10.1021/ed078p1266}} </ref><br />
<br />
|}<br />
<br />
===NCI===<br />
The non-covalent interactions (NCI) are interactions which are relatively weak in strength such as hydrogen bonds, Van der Walls and electrostatic attractions. The Shi catalyst with R,R-Stilbene transition state is chosen to be studied, it is mapped by downloading the .fchk file available at this {{DOI|10.6084/m9.figshare.832511}} and visualised using Gaussview. <br />
<br />
In the figure generated shows only two types of interactions, coded in green and yellow. The former means mild attractive interaction and the latter mildly repulsive interaction. It can be seen the amount (in terms of area) of attractive interaction greatly outweights repulsive ones. This is somewhat expected, because if the opposite is true the two molecules will be driven away from one another and no reaction would occur, meaning this would not be a transition state. <br />
The top part of the figure is the catalyst, and the bottom parts of the figure shows the stilbene species lying flat. It is observed the benzene rings on the reagent does not seem to be interacting with the catalyst in the NCI fashion at all. The major interaction comes from interaction between the fructose rings and the aliphatics of the stilbene.<br />
Important interactions that aids the formation of the transition state are pointed out below.<br />
<br />
[[File:NCI sw4512.PNG||800px|center]]<br />
<br />
===QTAIM===<br />
The same system is chosen as before here. The electronic topology of the system is mapped using Avogadro2 and the .wfn file downloaded at the {{DOI|10.6084/m9.figshare.832511}}, via the '''Molecular graph''' in '''Extension/QTAIM''' which stands for Quantum Theory of Atoms in Molecules. Yellow points between any two purple points indicate a bond critical point (BCP). Yellow points on solid lines indicate covalent interaction, when on dahsed line it means the interaction is non-covalent.<br />
<br />
One can see all the BCP for covalently bonded hetreoatoms (C-H, C-O) have the BCP away from the middle of the bond. Reflecting the relative eletropositivity of the hetroatoms (in C-H closer to H, in C-O closer to C). However, between all non-covalent interactions, BCPs more or less reside at the middle point. As there is a point of symmetry in the target reagent, one can split the alkene into two halfs. The figure below pinpoints some important non-covalent BCPs that aids the crossing of transition state to form epoxide product. <br />
<br />
[[File:QTAIM sw4512.PNG ||800px|center]]<br />
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==New Candidate for Investigation ==<br />
(R)-(+)-α-methylstyrene oxide is suitable candidate to undergo the computational investigation above. It has a CAS registry number of 2085-88-3 and a molecular weight of 134.178 g/mol. The precursor methylstyrene is readily available in the Sigma Aldrich catalog, with a CAS number of 98-83-9, and successful epoxidation process has been recorded in the literature <ref>Bogár, K. (2005). Oxidation of α-methylstyrene on an MCM-22 encapsulated (R, R)-(−)-N, N′-bis(3,5-di-tert-butylsalicylidene)-1,2-cyclohexanediaminocobalt(II) catalyst. Open Chemistry, 3(1), pp. 63-71. Retrieved 13 Mar. 2015, from {{doi|10.2478/BF02476238}}</ref>. The optical property measured in chloroform solution at 20 °C and 589 nm wavelength light is reported as -520.1°<ref>A. Archelas and and R. Furstoss, Absolute Configuration of α-Methylstyrene Oxide: The Correct Absolute Configuration/Optical Rotation Correlation, The Journal of Organic Chemistry 1999 64 (16), 6112-6114 {{DOI|10.1021/jo990474k.}}</ref><br />
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[[File:New candidate.PNG|300px]]<br />
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==References==<br />
<references /></div>Sw4512