ChemWiki - User contributions [en]

Rep:Mod:PhyComp101292

2014-03-21T16:59:30Z

Kwl11:

= Cope Rearrangement =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; APP orbital interactions, steric repulsions and The Van Der Wall's Forces. For vinyl, although there are no electronegative atoms, πC-C is a higher energy donor than σC-H meaning that the πC-C interacts better with the π*C-C app so APP arrangement of the two vinyl group is favourable. Vinyl group is relatively big so steric strain is reduced when they are APP with respect to each other. Therefore both factor 1 and 2 favours the APP arrangement.

In the HF/3-21G basis set, the gauche conformations were surprisingly more stable than the APP ones. Based on the factors explained above, we would expect the APP conformations to have lower energies than the gauche ones. The results were not as expected probably because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the πC-H-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. The smooth overlap of the πC-C→π*C-C also favours this arrangement. Anti 1 is more stable than anti 2 as the two vinyl groups are staggered while the vinyl groups of Anti 2 are eclipsed. Staggered is favoured over eclipsed which is why anti 1 is lower than anti 2 in energy. This model is accurate enough to account for electronic correlation giving the expected result.

The Bond Lengths and Angles of Anti 2 are summarised below

[[File:Kl_Bond_lengths_Anti_2.jpg]]‎

{| class="wikitable" border="1"
|+ Bond Lengths of Anti 2
! Bond !! HF/3-21G (A) !! B3LYP/6-31G* (A) !! Angle !! HF/3-21G !! B3LYP/6-31G*
|-
| C1-C2, C5-C6 || 1.32 || 1.33 || C1-C2-C3, C4-C5-C6 || 124.8 || 125.3
|-
| C2-C3, C4-C5 || 1.51 || 1.50 || C2-C3-C4, C3-C4-C5 || 111.3 || 112.7
|-
| C3-C4 || 1.55 || 1.55 || NA || NA || NA
|}

The bond lengths and angles are closer to experimental results in the B3LYP/6-31G* basis-sets.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

<pre>Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png|400px|left|]]

<pre> Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.</pre>

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

From this calculation, we can conclude that the the QST2 method will only locate the transtion state only if the structure of the reactant and product is reasonably close to the real structure of the transition state. Therefore this is a poor method if we know very little information about the real structure of the transition state. If we have good knowledge about the transitions state then this would be the most efficient method.

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

== Optimisation of The Transition State by B3LYP/6-31G* ==

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg|400px|left|]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

== Comparison of bond lengths between HF/3-21G and B3LYP/6-31G* ==

Both the force constant and the freezing coordinate method results in identical bond lengths

[[File:Kl_Bond_length_Chair.jpg‎]]

{| class="wikitable" border="1"
|+ Bond Lengths of Chair Transition State
! Bond !! Bond Length HF/3-21G (A) !! Bond Length B3LYP/6-31G* (A)
|-
| C10-C15, C2-C8 || 1.39 || 1.39
|-
| C10-C16, C2-C7 || 1.39 || 1.39
|-
| C8-C15, C7-C16 || 1.55 || 2.02
|}

The Bond Lengths of QST2 method is summarised below

{| class="wikitable" border="1"
|+ Bond Lengths of Boat Transition State
! Bond !! Bond Length HF/3-21G (A) !! Bond Length B3LYP/6-31G* (A)
|-
| C10-C15, C2-C8 || 1.38 || 1.39
|-
| C10-C16, C2-C7 || 1.38 || 1.39
|-
| C8-C15, C7-C16 || 2.14 || 2.21
|}

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gif|thumb|TS Mode of Vibration|centre|800px]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion so the bonds form synchronously where the atoms of both reactants are stretching vigously.

Compared to the first "Real" bending motion of the vibrational mode at 147 cm-1, the frequency corresponding to the TS vibrational mode is -956 cm-1 which is a lot higher in magnitude. This vibrational mode involves the stretching of both reactants which involves a lot more energy and hence a higher frequency than the simple bending motion in the first "Real" vibrational mode.

[[File:KlMode of 1st real vibration.gif|thumb|First Real Mode of Vibration|centre|800px]]

== Diels Alder Cycloaddition of Maleic Anhydride and Cyclohexadiene ==

Through this reaction, there are two possible transition states and this determines whether we get the exo or the endo product. Both the endo and exo transition state is optimised by Empirical/AM1 followed by B3LYP/6-31G*.

The log files can be found here: [[File:KL PART 3 DA exo (AM1).LOG]], [[File:kl Part 3 DA Endo (AM1).LOG]], [[File:KL PART 3 DA Exo 6-31G.LOG]], [[File:Kl Part 3 DA Endo (6-31G).LOG]]

The results are summarised below

{| class="wikitable" border="1"
|+ Exo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Exo (AM1) .jpg]] || [[File:Kl Exo (AM1) .jpg]]
|-
| Energy (a.u) || -0.05041966 || -612.67931094
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.17 || 2.29
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 2.94 || 3.03
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -812 || -449
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO35.jpg|200px|]] || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO34.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24216 || -0.07840
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

{| class="wikitable" border="1"
|+ Endo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Endo (AM1).jpg]] || [[File:Kl Endo (AM1).jpg]]
|-
| Energy (a.u) || -0.05150480 || -612.68339668
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.16 || 2.27
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 3.90 || 3.94
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -806 || -447
|}

The transition state was successfully optimised as the new sigma bond length between C2 and C8 and C5 and C7 are identical in both the Empirical/AM1 ( 2.16 A) and B3LYP/6-31G* (2.27 A) confirming that the new bonds are formed in a concerted manner. Furthermore, the presence of the imaginary frequency suggests that a energy maxima is achieved.

The endo and the exo structure differs by the orientation of the dienophile with respect to the diene. In the endo structure, the aldehyde is in the opposite phase with respect to the -CH2-Ch2- bridge whereas the aldehyde is in the same phase with the -CH2-Ch2- in the exo structure. From this point, we can see that the exo structure is sterically more hindered as there is a steric clash between the bridge and the aldehyde. This was illustrated in the B3LYP/6-31G* calculation where the distant between C3-C9/C4-C10 was 3.03 A in the exo structure and 3.94 A in the endo structure. Therefore the distant between the two groups are further apart in the endo structure making it energetically favoured due to less repulsion and hence lower in energy compared to the exo structure.

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]] || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24231 || -0.06773
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

From the above, all the MOs of the transition state were identified as anti-symmetric with respect to the plane. Based on the symmetry rules from the Woodward-Hoffmann, it is forbidden. The energy gap of the HOMO of the cyclohexadiene and LUMO of Maleic aldehyde was smaller than the energy gap of the HOMO of Maleic Aldehyde and the LUMO of cyclohexadiene . Since this reaction is kinetically control, the one with the smallest energy gap is favoured, ie the main orbital interactions leading the reaction is the overlap of the HOMO of cyclohexadiene and the LUMO of Maleic Aldehyde. Both of these orbital are anti-symmetric with respect to the plane which is why the MO transition state is assymetric with respect to the plane.

Secondary Orbital Overlap explains why the energy of the endo transition state is lower than the energy exo transition state. Secondary Orbital Overlap is defined by the bonding interaction of frontier orbitals between the atoms that are not involved in the sigma bond formation.

The following can be explained by the diagram below

[[File:Kl MO interactions.jpg]]

From the above, we can see that there are more favorable orbital overlaps in the endo structure than in the case of the exo structure. In the endo structure, there are secondary orbital overlap which is absent in the exo structure. These interactions stabilises the molecule, and this is the primary reason why the endo structure is favoured over the exo structure as well as the steric factor mentioned above.

The vibrational mode of the transition state was studied to determine whether the reaction proceeds via synchronously or asynchronously.

[[File:Kl imag freq DA 3.gif]]

The vibrational mode shown above is very similar to the one of the Diels Alder reaction between ethene and butadiene, ie both reactants stretch towards each other in a concerted motion. Therefore the bond formation is synchronous.

== Further Discussion ==

All the calculations was repeated with B3LYP/6-31G* as Empirical/AM1 fails to account for the effect of differential diatomic overlap. In the advanced B3LYP/6-31G*, the polarisation effect is accounted giving results that are more comparable to real experimental results.

The scope of this investigation was only limited to Normal Electron Demand of Diels Alder reaction, the Inverse Electron Demand of Diels Alder reaction was not covered. In this type of reaction, the energy of the LUMO of the diene lies higher in energy than the HOMO of the dienophile meaning that the flow of electrons will be reversed and hence the name Inverse Electron Demand. This type of reaction can be achieved when the diene is made electron deficient and the dienophile is made electron rich. This is an interesting reaction as it requires hetero atoms and forms hetero-aromatic species which can be useful in the pharmaceutical industry. Therefore, it will be beneficial to study this type of reaction.

Another important factor which was neglected throughout this computational exercise was the regio-selectivity. There was no issue with regio-seletivity in the examples that were covered but in reality changing the electronegativity of the substituents can alter the regioselectivity and this could be investigated with Frontier Molecular Orbital analysis.

There are many other factors that could have been investigated such as the temperature and solvent employed during the reaction. Gaussview has the ability to change these settings and this allows us to investigate whether there would be any changes in energy and selectivity.

Rep:Mod:PhyComp101292

2014-03-21T16:58:41Z

Kwl11:

= Cope Rearrangement =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; APP orbital interactions, steric repulsions and The Van Der Wall's Forces. For vinyl, although there are no electronegative atoms, πC-C is a higher energy donor than σC-H meaning that the πC-C interacts better with the π*C-C app so APP arrangement of the two vinyl group is favourable. Vinyl group is relatively big so steric strain is reduced when they are APP with respect to each other. Therefore both factor 1 and 2 favours the APP arrangement.

In the HF/3-21G basis set, the gauche conformations were surprisingly more stable than the APP ones. Based on the factors explained above, we would expect the APP conformations to have lower energies than the gauche ones. The results were not as expected probably because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the πC-H-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. The smooth overlap of the πC-C→π*C-C also favours this arrangement. Anti 1 is more stable than anti 2 as the two vinyl groups are staggered while the vinyl groups of Anti 2 are eclipsed. Staggered is favoured over eclipsed which is why anti 1 is lower than anti 2 in energy. This model is accurate enough to account for electronic correlation giving the expected result.

The Bond Lengths and Angles of Anti 2 are summarised below

[[File:Kl_Bond_lengths_Anti_2.jpg]]‎

{| class="wikitable" border="1"
|+ Bond Lengths of Anti 2
! Bond !! HF/3-21G (A) !! B3LYP/6-31G* (A) !! Angle !! HF/3-21G !! B3LYP/6-31G*
|-
| C1-C2, C5-C6 || 1.32 || 1.33 || C1-C2-C3, C4-C5-C6 || 124.8 || 125.3
|-
| C2-C3, C4-C5 || 1.51 || 1.50 || C2-C3-C4, C3-C4-C5 || 111.3 || 112.7
|-
| C3-C4 || 1.55 || 1.55 || NA || NA || NA
|}

The bond lengths and angles are closer to experimental results in the B3LYP/6-31G* basis-sets.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

<pre>Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png|400px|left|]]

<pre> Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.</pre>

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

From this calculation, we can conclude that the the QST2 method will only locate the transtion state only if the structure of the reactant and product is reasonably close to the real structure of the transition state. Therefore this is a poor method if we know very little information about the real structure of the transition state. If we have good knowledge about the transitions state then this would be the most efficient method.

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

== Optimisation of The Transition State by B3LYP/6-31G* ==

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg|400px|left|]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

== Comparison of bond lengths between HF/3-21G and B3LYP/6-31G* ==

Both the force constant and the freezing coordinate method results in identical bond lengths

[[File:Kl_Bond_length_Chair.jpg‎]]

{| class="wikitable" border="1"
|+ Bond Lengths of Chair Transition State
! Bond !! Bond Length HF/3-21G (A) !! Bond Length B3LYP/6-31G* (A)
|-
| C10-C15, C2-C8 || 1.39 || 1.39
|-
| C10-C16, C2-C7 || 1.39 || 1.39
|-
| C8-C15, C7-C16 || 1.55 || 2.02
|}

The Bond Lengths of QST2 method is summarised below

{| class="wikitable" border="1"
|+ Bond Lengths of Chair Transition State
! Bond !! Bond Length HF/3-21G (A) !! Bond Length B3LYP/6-31G* (A)
|-
| C10-C15, C2-C8 || 1.38 || 1.39
|-
| C10-C16, C2-C7 || 1.38 || 1.39
|-
| C8-C15, C7-C16 || 2.14 || 2.21
|}

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gif|thumb|TS Mode of Vibration|centre|800px]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion so the bonds form synchronously where the atoms of both reactants are stretching vigously.

Compared to the first "Real" bending motion of the vibrational mode at 147 cm-1, the frequency corresponding to the TS vibrational mode is -956 cm-1 which is a lot higher in magnitude. This vibrational mode involves the stretching of both reactants which involves a lot more energy and hence a higher frequency than the simple bending motion in the first "Real" vibrational mode.

[[File:KlMode of 1st real vibration.gif|thumb|First Real Mode of Vibration|centre|800px]]

== Diels Alder Cycloaddition of Maleic Anhydride and Cyclohexadiene ==

Through this reaction, there are two possible transition states and this determines whether we get the exo or the endo product. Both the endo and exo transition state is optimised by Empirical/AM1 followed by B3LYP/6-31G*.

The log files can be found here: [[File:KL PART 3 DA exo (AM1).LOG]], [[File:kl Part 3 DA Endo (AM1).LOG]], [[File:KL PART 3 DA Exo 6-31G.LOG]], [[File:Kl Part 3 DA Endo (6-31G).LOG]]

The results are summarised below

{| class="wikitable" border="1"
|+ Exo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Exo (AM1) .jpg]] || [[File:Kl Exo (AM1) .jpg]]
|-
| Energy (a.u) || -0.05041966 || -612.67931094
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.17 || 2.29
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 2.94 || 3.03
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -812 || -449
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO35.jpg|200px|]] || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO34.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24216 || -0.07840
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

{| class="wikitable" border="1"
|+ Endo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Endo (AM1).jpg]] || [[File:Kl Endo (AM1).jpg]]
|-
| Energy (a.u) || -0.05150480 || -612.68339668
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.16 || 2.27
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 3.90 || 3.94
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -806 || -447
|}

The transition state was successfully optimised as the new sigma bond length between C2 and C8 and C5 and C7 are identical in both the Empirical/AM1 ( 2.16 A) and B3LYP/6-31G* (2.27 A) confirming that the new bonds are formed in a concerted manner. Furthermore, the presence of the imaginary frequency suggests that a energy maxima is achieved.

The endo and the exo structure differs by the orientation of the dienophile with respect to the diene. In the endo structure, the aldehyde is in the opposite phase with respect to the -CH2-Ch2- bridge whereas the aldehyde is in the same phase with the -CH2-Ch2- in the exo structure. From this point, we can see that the exo structure is sterically more hindered as there is a steric clash between the bridge and the aldehyde. This was illustrated in the B3LYP/6-31G* calculation where the distant between C3-C9/C4-C10 was 3.03 A in the exo structure and 3.94 A in the endo structure. Therefore the distant between the two groups are further apart in the endo structure making it energetically favoured due to less repulsion and hence lower in energy compared to the exo structure.

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]] || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24231 || -0.06773
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

From the above, all the MOs of the transition state were identified as anti-symmetric with respect to the plane. Based on the symmetry rules from the Woodward-Hoffmann, it is forbidden. The energy gap of the HOMO of the cyclohexadiene and LUMO of Maleic aldehyde was smaller than the energy gap of the HOMO of Maleic Aldehyde and the LUMO of cyclohexadiene . Since this reaction is kinetically control, the one with the smallest energy gap is favoured, ie the main orbital interactions leading the reaction is the overlap of the HOMO of cyclohexadiene and the LUMO of Maleic Aldehyde. Both of these orbital are anti-symmetric with respect to the plane which is why the MO transition state is assymetric with respect to the plane.

Secondary Orbital Overlap explains why the energy of the endo transition state is lower than the energy exo transition state. Secondary Orbital Overlap is defined by the bonding interaction of frontier orbitals between the atoms that are not involved in the sigma bond formation.

The following can be explained by the diagram below

[[File:Kl MO interactions.jpg]]

From the above, we can see that there are more favorable orbital overlaps in the endo structure than in the case of the exo structure. In the endo structure, there are secondary orbital overlap which is absent in the exo structure. These interactions stabilises the molecule, and this is the primary reason why the endo structure is favoured over the exo structure as well as the steric factor mentioned above.

The vibrational mode of the transition state was studied to determine whether the reaction proceeds via synchronously or asynchronously.

[[File:Kl imag freq DA 3.gif]]

The vibrational mode shown above is very similar to the one of the Diels Alder reaction between ethene and butadiene, ie both reactants stretch towards each other in a concerted motion. Therefore the bond formation is synchronous.

== Further Discussion ==

All the calculations was repeated with B3LYP/6-31G* as Empirical/AM1 fails to account for the effect of differential diatomic overlap. In the advanced B3LYP/6-31G*, the polarisation effect is accounted giving results that are more comparable to real experimental results.

The scope of this investigation was only limited to Normal Electron Demand of Diels Alder reaction, the Inverse Electron Demand of Diels Alder reaction was not covered. In this type of reaction, the energy of the LUMO of the diene lies higher in energy than the HOMO of the dienophile meaning that the flow of electrons will be reversed and hence the name Inverse Electron Demand. This type of reaction can be achieved when the diene is made electron deficient and the dienophile is made electron rich. This is an interesting reaction as it requires hetero atoms and forms hetero-aromatic species which can be useful in the pharmaceutical industry. Therefore, it will be beneficial to study this type of reaction.

Another important factor which was neglected throughout this computational exercise was the regio-selectivity. There was no issue with regio-seletivity in the examples that were covered but in reality changing the electronegativity of the substituents can alter the regioselectivity and this could be investigated with Frontier Molecular Orbital analysis.

There are many other factors that could have been investigated such as the temperature and solvent employed during the reaction. Gaussview has the ability to change these settings and this allows us to investigate whether there would be any changes in energy and selectivity.

Rep:Mod:PhyComp101292

2014-03-21T16:42:24Z

Kwl11:

= Cope Rearrangement =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; APP orbital interactions, steric repulsions and The Van Der Wall's Forces. For vinyl, although there are no electronegative atoms, πC-C is a higher energy donor than σC-H meaning that the πC-C interacts better with the π*C-C app so APP arrangement of the two vinyl group is favourable. Vinyl group is relatively big so steric strain is reduced when they are APP with respect to each other. Therefore both factor 1 and 2 favours the APP arrangement.

In the HF/3-21G basis set, the gauche conformations were surprisingly more stable than the APP ones. Based on the factors explained above, we would expect the APP conformations to have lower energies than the gauche ones. The results were not as expected probably because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the πC-H-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. The smooth overlap of the πC-C→π*C-C also favours this arrangement. Anti 1 is more stable than anti 2 as the two vinyl groups are staggered while the vinyl groups of Anti 2 are eclipsed. Staggered is favoured over eclipsed which is why anti 1 is lower than anti 2 in energy. This model is accurate enough to account for electronic correlation giving the expected result.

The Bond Lengths and Angles of Anti 2 are summarised below

[[File:Kl_Bond_lengths_Anti_2.jpg]]‎

{| class="wikitable" border="1"
|+ Bond Lengths of Anti 2
! Bond !! HF/3-21G (A) !! B3LYP/6-31G* (A) !! Angle !! HF/3-21G !! B3LYP/6-31G*
|-
| C1-C2, C5-C6 || 1.32 || 1.33 || C1-C2-C3, C4-C5-C6 || 124.8 || 125.3
|-
| C2-C3, C4-C5 || 1.51 || 1.50 || C2-C3-C4, C3-C4-C5 || 111.3 || 112.7
|-
| C3-C4 || 1.55 || 1.55 || NA || NA || NA
|}

The bond lengths and angles are closer to experimental results in the B3LYP/6-31G* basis-sets.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

<pre>Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png|400px|left|]]

<pre> Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.</pre>

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

From this calculation, we can conclude that the the QST2 method will only locate the transtion state only if the structure of the reactant and product is reasonably close to the real structure of the transition state. Therefore this is a poor method if we know very little information about the real structure of the transition state. If we have good knowledge about the transitions state then this would be the most efficient method.

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

== Optimisation of The Transition State by B3LYP/6-31G* ==

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg|400px|left|]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

== Comparison of bond lengths between HF/3-21G and B3LYP/6-31G* ==

Both the force constant and the freezing coordinate method results in identical bond lengths

[[File:Kl_Bond_length_Chair.jpg‎]]

{| class="wikitable" border="1"
|+ Bond Lengths of Chair Transition State
! Bond !! Bond Length HF/3-21G (A) !! Bond Length B3LYP/6-31G* (A)
|-
| C10-C15, C2-C8 || 1.39 || 1.39
|-
| C10-C16, C2-C7 || 1.39 || 1.39
|-
| C8-C15, C7-C16 || 1.55 || 2.02
|}

The Bond Lengths of QST2 method is summarised below

{| class="wikitable" border="1"
|+ Bond Lengths of Chair Transition State
! Bond !! Bond Length HF/3-21G (A) !! Bond Length B3LYP/6-31G* (A)
|-
| C10-C15, C2-C8 || 1.39 || 1.39
|-
| C10-C16, C2-C7 || 1.39 || 1.39
|-
| C8-C15, C7-C16 || {| class="wikitable" border="1"
|+ Bond Lengths of Chair Transition State
! Bond !! Bond Length HF/3-21G (A) !! Bond Length B3LYP/6-31G* (A)
|-
| C10-C15, C2-C8 || 1.38 || 1.39
|-
| C10-C16, C2-C7 || 1.38 || 1.39
|-
| C8-C15, C7-C16 || 2.14 || 2.21
|}

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gif|thumb|TS Mode of Vibration|centre|800px]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion so the bonds form synchronously where the atoms of both reactants are stretching vigously.

Compared to the first "Real" bending motion of the vibrational mode at 147 cm-1, the frequency corresponding to the TS vibrational mode is -956 cm-1 which is a lot higher in magnitude. This vibrational mode involves the stretching of both reactants which involves a lot more energy and hence a higher frequency than the simple bending motion in the first "Real" vibrational mode.

[[File:KlMode of 1st real vibration.gif|thumb|First Real Mode of Vibration|centre|800px]]

== Diels Alder Cycloaddition of Maleic Anhydride and Cyclohexadiene ==

Through this reaction, there are two possible transition states and this determines whether we get the exo or the endo product. Both the endo and exo transition state is optimised by Empirical/AM1 followed by B3LYP/6-31G*.

The log files can be found here: [[File:KL PART 3 DA exo (AM1).LOG]], [[File:kl Part 3 DA Endo (AM1).LOG]], [[File:KL PART 3 DA Exo 6-31G.LOG]], [[File:Kl Part 3 DA Endo (6-31G).LOG]]

The results are summarised below

{| class="wikitable" border="1"
|+ Exo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Exo (AM1) .jpg]] || [[File:Kl Exo (AM1) .jpg]]
|-
| Energy (a.u) || -0.05041966 || -612.67931094
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.17 || 2.29
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 2.94 || 3.03
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -812 || -449
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO35.jpg|200px|]] || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO34.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24216 || -0.07840
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

{| class="wikitable" border="1"
|+ Endo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Endo (AM1).jpg]] || [[File:Kl Endo (AM1).jpg]]
|-
| Energy (a.u) || -0.05150480 || -612.68339668
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.16 || 2.27
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 3.90 || 3.94
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -806 || -447
|}

The transition state was successfully optimised as the new sigma bond length between C2 and C8 and C5 and C7 are identical in both the Empirical/AM1 ( 2.16 A) and B3LYP/6-31G* (2.27 A) confirming that the new bonds are formed in a concerted manner. Furthermore, the presence of the imaginary frequency suggests that a energy maxima is achieved.

The endo and the exo structure differs by the orientation of the dienophile with respect to the diene. In the endo structure, the aldehyde is in the opposite phase with respect to the -CH2-Ch2- bridge whereas the aldehyde is in the same phase with the -CH2-Ch2- in the exo structure. From this point, we can see that the exo structure is sterically more hindered as there is a steric clash between the bridge and the aldehyde. This was illustrated in the B3LYP/6-31G* calculation where the distant between C3-C9/C4-C10 was 3.03 A in the exo structure and 3.94 A in the endo structure. Therefore the distant between the two groups are further apart in the endo structure making it energetically favoured due to less repulsion and hence lower in energy compared to the exo structure.

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]] || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24231 || -0.06773
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

From the above, all the MOs of the transition state were identified as anti-symmetric with respect to the plane. Based on the symmetry rules from the Woodward-Hoffmann, it is forbidden. The energy gap of the HOMO of the cyclohexadiene and LUMO of Maleic aldehyde was smaller than the energy gap of the HOMO of Maleic Aldehyde and the LUMO of cyclohexadiene . Since this reaction is kinetically control, the one with the smallest energy gap is favoured, ie the main orbital interactions leading the reaction is the overlap of the HOMO of cyclohexadiene and the LUMO of Maleic Aldehyde. Both of these orbital are anti-symmetric with respect to the plane which is why the MO transition state is assymetric with respect to the plane.

Secondary Orbital Overlap explains why the energy of the endo transition state is lower than the energy exo transition state. Secondary Orbital Overlap is defined by the bonding interaction of frontier orbitals between the atoms that are not involved in the sigma bond formation.

The following can be explained by the diagram below

[[File:Kl MO interactions.jpg]]

From the above, we can see that there are more favorable orbital overlaps in the endo structure than in the case of the exo structure. In the endo structure, there are secondary orbital overlap which is absent in the exo structure. These interactions stabilises the molecule, and this is the primary reason why the endo structure is favoured over the exo structure as well as the steric factor mentioned above.

The vibrational mode of the transition state was studied to determine whether the reaction proceeds via synchronously or asynchronously.

[[File:Kl imag freq DA 3.gif]]

The vibrational mode shown above is very similar to the one of the Diels Alder reaction between ethene and butadiene, ie both reactants stretch towards each other in a concerted motion. Therefore the bond formation is synchronous.

== Further Discussion ==

All the calculations was repeated with B3LYP/6-31G* as Empirical/AM1 fails to account for the effect of differential diatomic overlap. In the advanced B3LYP/6-31G*, the polarisation effect is accounted giving results that are more comparable to real experimental results.

The scope of this investigation was only limited to Normal Electron Demand of Diels Alder reaction, the Inverse Electron Demand of Diels Alder reaction was not covered. In this type of reaction, the energy of the LUMO of the diene lies higher in energy than the HOMO of the dienophile meaning that the flow of electrons will be reversed and hence the name Inverse Electron Demand. This type of reaction can be achieved when the diene is made electron deficient and the dienophile is made electron rich. This is an interesting reaction as it requires hetero atoms and forms hetero-aromatic species which can be useful in the pharmaceutical industry. Therefore, it will be beneficial to study this type of reaction.

Another important factor which was neglected throughout this computational exercise was the regio-selectivity. There was no issue with regio-seletivity in the examples that were covered but in reality changing the electronegativity of the substituents can alter the regioselectivity and this could be investigated with Frontier Molecular Orbital analysis.

There are many other factors that could have been investigated such as the temperature and solvent employed during the reaction. Gaussview has the ability to change these settings and this allows us to investigate whether there would be any changes in energy and selectivity.

File:Kl Bond length Chair.jpg

2014-03-21T16:26:24Z

Kwl11:

File:Kl Bond lengths Anti 2.jpg

2014-03-21T15:54:37Z

Kwl11:

Rep:Mod:PhyComp101292

2014-03-21T14:30:48Z

Kwl11:

= Cope Rearrangement =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; the effect of stabilising σC-H → σ*C-H and σC-C → σ*C-C orbital interactions, steric repulsions and The Van Der Wall's Forces. For n-butane, the energy levels of the donors and acceptors are all very similar since the electronegativity of all the atoms in the molecule are very similar so the 1st effect makes very little difference in deciding which conformation has a lower energy. Ethylene group is relatively big so steric strain is reduced when they are APP with respect to each other meaning that factor two favours the APP arrangement.

In the HF/3-21G basis set, gauche conformations are more stable than the APP ones but the reverse is observed in the B3LYP/6-31G* set. Based on the three factors explained above, we would expect expect the APP conformations to have lower energies than the gauche ones. This is because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the σC-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. This model is accurate enough to account for electronic correlation giving the expected result.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

<pre>Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png]]

<pre> Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.</pre>

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

== Optimisation of The Transition State by B3LYP/6-31G* ==

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gif|thumb|TS Mode of Vibration|centre|800px]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion so the bonds form synchronously where the atoms of both reactants are stretching vigously.

Compared to the first "Real" bending motion of the vibrational mode at 147 cm-1, the frequency corresponding to the TS vibrational mode is -956 cm-1 which is a lot higher in magnitude. This vibrational mode involves the stretching of both reactants which involves a lot more energy and hence a higher frequency than the simple bending motion in the first "Real" vibrational mode.

[[File:KlMode of 1st real vibration.gif|thumb|First Real Mode of Vibration|centre|800px]]

== Diels Alder Cycloaddition of Maleic Anhydride and Cyclohexadiene ==

Through this reaction, there are two possible transition states and this determines whether we get the exo or the endo product. Both the endo and exo transition state is optimised by Empirical/AM1 followed by B3LYP/6-31G*.

The log files can be found here: [[File:KL PART 3 DA exo (AM1).LOG]], [[File:kl Part 3 DA Endo (AM1).LOG]], [[File:KL PART 3 DA Exo 6-31G.LOG]], [[File:Kl Part 3 DA Endo (6-31G).LOG]]

The results are summarised below

{| class="wikitable" border="1"
|+ Exo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Exo (AM1) .jpg]] || [[File:Kl Exo (AM1) .jpg]]
|-
| Energy (a.u) || -0.05041966 || -612.67931094
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.17 || 2.29
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 2.94 || 3.03
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -812 || -449
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO35.jpg|200px|]] || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO34.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24216 || -0.07840
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

{| class="wikitable" border="1"
|+ Endo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Endo (AM1).jpg]] || [[File:Kl Endo (AM1).jpg]]
|-
| Energy (a.u) || -0.05150480 || -612.68339668
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.16 || 2.27
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 3.90 || 3.94
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -806 || -447
|}

The transition state was successfully optimised as the new sigma bond length between C2 and C8 and C5 and C7 are identical in both the Empirical/AM1 ( 2.16 A) and B3LYP/6-31G* (2.27 A) confirming that the new bonds are formed in a concerted manner. Furthermore, the presence of the imaginary frequency suggests that a energy maxima is achieved.

The endo and the exo structure differs by the orientation of the dienophile with respect to the diene. In the endo structure, the aldehyde is in the opposite phase with respect to the -CH2-Ch2- bridge whereas the aldehyde is in the same phase with the -CH2-Ch2- in the exo structure. From this point, we can see that the exo structure is sterically more hindered as there is a steric clash between the bridge and the aldehyde. This was illustrated in the B3LYP/6-31G* calculation where the distant between C3-C9/C4-C10 was 3.03 A in the exo structure and 3.94 A in the endo structure. Therefore the distant between the two groups are further apart in the endo structure making it energetically favoured due to less repulsion and hence lower in energy compared to the exo structure.

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]] || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24231 || -0.06773
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

From the above, all the MOs of the transition state were identified as anti-symmetric with respect to the plane. Based on the symmetry rules from the Woodward-Hoffmann, it is forbidden. The energy gap of the HOMO of the cyclohexadiene and LUMO of Maleic aldehyde was smaller than the energy gap of the HOMO of Maleic Aldehyde and the LUMO of cyclohexadiene . Since this reaction is kinetically control, the one with the smallest energy gap is favoured, ie the main orbital interactions leading the reaction is the overlap of the HOMO of cyclohexadiene and the LUMO of Maleic Aldehyde. Both of these orbital are anti-symmetric with respect to the plane which is why the MO transition state is assymetric with respect to the plane.

Secondary Orbital Overlap explains why the energy of the endo transition state is lower than the energy exo transition state. Secondary Orbital Overlap is defined by the bonding interaction of frontier orbitals between the atoms that are not involved in the sigma bond formation.

The following can be explained by the diagram below

[[File:Kl MO interactions.jpg]]

From the above, we can see that there are more favorable orbital overlaps in the endo structure than in the case of the exo structure. In the endo structure, there are secondary orbital overlap which is absent in the exo structure. These interactions stabilises the molecule, and this is the primary reason why the endo structure is favoured over the exo structure as well as the steric factor mentioned above.

The vibrational mode of the transition state was studied to determine whether the reaction proceeds via synchronously or asynchronously.

[[File:Kl imag freq DA 3.gif]]

The vibrational mode shown above is very similar to the one of the Diels Alder reaction between ethene and butadiene, ie both reactants stretch towards each other in a concerted motion. Therefore the bond formation is synchronous.

== Further Discussion ==

All the calculations was repeated with B3LYP/6-31G* as Empirical/AM1 fails to account for the effect of differential diatomic overlap. In the advanced B3LYP/6-31G*, the polarisation effect is accounted giving results that are more comparable to real experimental results.

The scope of this investigation was only limited to Normal Electron Demand of Diels Alder reaction, the Inverse Electron Demand of Diels Alder reaction was not covered. In this type of reaction, the energy of the LUMO of the diene lies higher in energy than the HOMO of the dienophile meaning that the flow of electrons will be reversed and hence the name Inverse Electron Demand. This type of reaction can be achieved when the diene is made electron deficient and the dienophile is made electron rich. This is an interesting reaction as it requires hetero atoms and forms hetero-aromatic species which can be useful in the pharmaceutical industry. Therefore, it will be beneficial to study this type of reaction.

Another important factor which was neglected throughout this computational exercise was the regio-selectivity. There was no issue with regio-seletivity in the examples that were covered but in reality changing the electronegativity of the substituents can alter the regioselectivity and this could be investigated with Frontier Molecular Orbital analysis.

There are many other factors that could have been investigated such as the temperature and solvent employed during the reaction. Gaussview has the ability to change these settings and this allows us to investigate whether there would be any changes in energy and selectivity.

Rep:Mod:PhyComp101292

2014-03-21T14:29:09Z

Kwl11:

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; the effect of stabilising σC-H → σ*C-H and σC-C → σ*C-C orbital interactions, steric repulsions and The Van Der Wall's Forces. For n-butane, the energy levels of the donors and acceptors are all very similar since the electronegativity of all the atoms in the molecule are very similar so the 1st effect makes very little difference in deciding which conformation has a lower energy. Ethylene group is relatively big so steric strain is reduced when they are APP with respect to each other meaning that factor two favours the APP arrangement.

In the HF/3-21G basis set, gauche conformations are more stable than the APP ones but the reverse is observed in the B3LYP/6-31G* set. Based on the three factors explained above, we would expect expect the APP conformations to have lower energies than the gauche ones. This is because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the σC-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. This model is accurate enough to account for electronic correlation giving the expected result.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

<pre>Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png]]

<pre> Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.</pre>

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

== Optimisation of The Transition State by B3LYP/6-31G* ==

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gif|thumb|TS Mode of Vibration|centre|800px]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion so the bonds form synchronously where the atoms of both reactants are stretching vigously.

Compared to the first "Real" bending motion of the vibrational mode at 147 cm-1, the frequency corresponding to the TS vibrational mode is -956 cm-1 which is a lot higher in magnitude. This vibrational mode involves the stretching of both reactants which involves a lot more energy and hence a higher frequency than the simple bending motion in the first "Real" vibrational mode.

[[File:KlMode of 1st real vibration.gif|thumb|First Real Mode of Vibration|centre|800px]]

== Diels Alder Cycloaddition of Maleic Anhydride and Cyclohexadiene ==

Through this reaction, there are two possible transition states and this determines whether we get the exo or the endo product. Both the endo and exo transition state is optimised by Empirical/AM1 followed by B3LYP/6-31G*.

The log files can be found here: [[File:KL PART 3 DA exo (AM1).LOG]], [[File:kl Part 3 DA Endo (AM1).LOG]], [[File:KL PART 3 DA Exo 6-31G.LOG]], [[File:Kl Part 3 DA Endo (6-31G).LOG]]

The results are summarised below

{| class="wikitable" border="1"
|+ Exo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Exo (AM1) .jpg]] || [[File:Kl Exo (AM1) .jpg]]
|-
| Energy (a.u) || -0.05041966 || -612.67931094
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.17 || 2.29
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 2.94 || 3.03
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -812 || -449
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO35.jpg|200px|]] || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO34.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24216 || -0.07840
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

{| class="wikitable" border="1"
|+ Endo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Endo (AM1).jpg]] || [[File:Kl Endo (AM1).jpg]]
|-
| Energy (a.u) || -0.05150480 || -612.68339668
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.16 || 2.27
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 3.90 || 3.94
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -806 || -447
|}

The transition state was successfully optimised as the new sigma bond length between C2 and C8 and C5 and C7 are identical in both the Empirical/AM1 ( 2.16 A) and B3LYP/6-31G* (2.27 A) confirming that the new bonds are formed in a concerted manner. Furthermore, the presence of the imaginary frequency suggests that a energy maxima is achieved.

The endo and the exo structure differs by the orientation of the dienophile with respect to the diene. In the endo structure, the aldehyde is in the opposite phase with respect to the -CH2-Ch2- bridge whereas the aldehyde is in the same phase with the -CH2-Ch2- in the exo structure. From this point, we can see that the exo structure is sterically more hindered as there is a steric clash between the bridge and the aldehyde. This was illustrated in the B3LYP/6-31G* calculation where the distant between C3-C9/C4-C10 was 3.03 A in the exo structure and 3.94 A in the endo structure. Therefore the distant between the two groups are further apart in the endo structure making it energetically favoured due to less repulsion and hence lower in energy compared to the exo structure.

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]] || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24231 || -0.06773
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

From the above, all the MOs of the transition state were identified as anti-symmetric with respect to the plane. Based on the symmetry rules from the Woodward-Hoffmann, it is forbidden. The energy gap of the HOMO of the cyclohexadiene and LUMO of Maleic aldehyde was smaller than the energy gap of the HOMO of Maleic Aldehyde and the LUMO of cyclohexadiene . Since this reaction is kinetically control, the one with the smallest energy gap is favoured, ie the main orbital interactions leading the reaction is the overlap of the HOMO of cyclohexadiene and the LUMO of Maleic Aldehyde. Both of these orbital are anti-symmetric with respect to the plane which is why the MO transition state is assymetric with respect to the plane.

Secondary Orbital Overlap explains why the energy of the endo transition state is lower than the energy exo transition state. Secondary Orbital Overlap is defined by the bonding interaction of frontier orbitals between the atoms that are not involved in the sigma bond formation.

The following can be explained by the diagram below

[[File:Kl MO interactions.jpg]]

From the above, we can see that there are more favorable orbital overlaps in the endo structure than in the case of the exo structure. In the endo structure, there are secondary orbital overlap which is absent in the exo structure. These interactions stabilises the molecule, and this is the primary reason why the endo structure is favoured over the exo structure as well as the steric factor mentioned above.

The vibrational mode of the transition state was studied to determine whether the reaction proceeds via synchronously or asynchronously.

[[File:Kl imag freq DA 3.gif]]

The vibrational mode shown above is very similar to the one of the Diels Alder reaction between ethene and butadiene, ie both reactants stretch towards each other in a concerted motion. Therefore the bond formation is synchronous.

== Further Discussion ==

All the calculations was repeated with B3LYP/6-31G* as Empirical/AM1 fails to account for the effect of differential diatomic overlap. In the advanced B3LYP/6-31G*, the polarisation effect is accounted giving results that are more comparable to real experimental results.

The scope of this investigation was only limited to Normal Electron Demand of Diels Alder reaction, the Inverse Electron Demand of Diels Alder reaction was not covered. In this type of reaction, the energy of the LUMO of the diene lies higher in energy than the HOMO of the dienophile meaning that the flow of electrons will be reversed and hence the name Inverse Electron Demand. This type of reaction can be achieved when the diene is made electron deficient and the dienophile is made electron rich. This is an interesting reaction as it requires hetero atoms and forms hetero-aromatic species which can be useful in the pharmaceutical industry. Therefore, it will be beneficial to study this type of reaction.

Another important factor which was neglected throughout this computational exercise was the regio-selectivity. There was no issue with regio-seletivity in the examples that were covered but in reality changing the electronegativity of the substituents can alter the regioselectivity and this could be investigated with Frontier Molecular Orbital analysis.

There are many other factors that could have been investigated such as the temperature and solvent employed during the reaction. Gaussview has the ability to change these settings and this allows us to investigate whether there would be any changes in energy and selectivity.

Rep:Mod:PhyComp101292

2014-03-21T13:27:50Z

Kwl11:

= '''Cope Rearrangement''' =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; the effect of stabilising σC-H → σ*C-H and σC-C → σ*C-C orbital interactions, steric repulsions and The Van Der Wall's Forces. For n-butane, the energy levels of the donors and acceptors are all very similar since the electronegativity of all the atoms in the molecule are very similar so the 1st effect makes very little difference in deciding which conformation has a lower energy. Ethylene group is relatively big so steric strain is reduced when they are APP with respect to each other meaning that factor two favours the APP arrangement.

In the HF/3-21G basis set, gauche conformations are more stable than the APP ones but the reverse is observed in the B3LYP/6-31G* set. Based on the three factors explained above, we would expect expect the APP conformations to have lower energies than the gauche ones. This is because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the σC-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. This model is accurate enough to account for electronic correlation giving the expected result.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

<pre>Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png]]

<pre> Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.</pre>

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

== Optimisation of The Transition State by B3LYP/6-31G* ==

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gif|thumb|TS Mode of Vibration|centre|800px]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion so the bonds form synchronously where the atoms of both reactants are stretching vigously.

Compared to the first "Real" bending motion of the vibrational mode at 147 cm-1, the frequency corresponding to the TS vibrational mode is -956 cm-1 which is a lot higher in magnitude. This vibrational mode involves the stretching of both reactants which involves a lot more energy and hence a higher frequency than the simple bending motion in the first "Real" vibrational mode.

[[File:KlMode of 1st real vibration.gif|thumb|First Real Mode of Vibration|centre|800px]]

== Diels Alder Cycloaddition of Maleic Anhydride and Cyclohexadiene ==

Through this reaction, there are two possible transition states and this determines whether we get the exo or the endo product. Both the endo and exo transition state is optimised by Empirical/AM1 followed by B3LYP/6-31G*.

The log files can be found here: [[File:KL PART 3 DA exo (AM1).LOG]], [[File:kl Part 3 DA Endo (AM1).LOG]], [[File:KL PART 3 DA Exo 6-31G.LOG]], [[File:Kl Part 3 DA Endo (6-31G).LOG]]

The results are summarised below

{| class="wikitable" border="1"
|+ Exo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Exo (AM1) .jpg]] || [[File:Kl Exo (AM1) .jpg]]
|-
| Energy (a.u) || -0.05041966 || -612.67931094
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.17 || 2.29
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 2.94 || 3.03
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -812 || -449
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO35.jpg|200px|]] || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO34.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24216 || -0.07840
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

{| class="wikitable" border="1"
|+ Endo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Endo (AM1).jpg]] || [[File:Kl Endo (AM1).jpg]]
|-
| Energy (a.u) || -0.05150480 || -612.68339668
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.16 || 2.27
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 3.90 || 3.94
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -806 || -447
|}

The transition state was successfully optimised as the new sigma bond length between C2 and C8 and C5 and C7 are identical in both the Empirical/AM1 ( 2.16 A) and B3LYP/6-31G* (2.27 A) confirming that the new bonds are formed in a concerted manner. Furthermore, the presence of the imaginary frequency suggests that a energy maxima is achieved.

The endo and the exo structure differs by the orientation of the dienophile with respect to the diene. In the endo structure, the aldehyde is in the opposite phase with respect to the -CH2-Ch2- bridge whereas the aldehyde is in the same phase with the -CH2-Ch2- in the exo structure. From this point, we can see that the exo structure is sterically more hindered as there is a steric clash between the bridge and the aldehyde. This was illustrated in the B3LYP/6-31G* calculation where the distant between C3-C9/C4-C10 was 3.03 A in the exo structure and 3.94 A in the endo structure. Therefore the distant between the two groups are further apart in the endo structure making it energetically favoured due to less repulsion and hence lower in energy compared to the exo structure.

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]] || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24231 || -0.06773
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

From the above, all the MOs of the transition state were identified as anti-symmetric with respect to the plane. Based on the symmetry rules from the Woodward-Hoffmann, it is forbidden. The energy gap of the HOMO of the cyclohexadiene and LUMO of Maleic aldehyde was smaller than the energy gap of the HOMO of Maleic Aldehyde and the LUMO of cyclohexadiene . Since this reaction is kinetically control, the one with the smallest energy gap is favoured, ie the main orbital interactions leading the reaction is the overlap of the HOMO of cyclohexadiene and the LUMO of Maleic Aldehyde. Both of these orbital are anti-symmetric with respect to the plane which is why the MO transition state is assymetric with respect to the plane.

Secondary Orbital Overlap explains why the energy of the endo transition state is lower than the energy exo transition state. Secondary Orbital Overlap is defined by the bonding interaction of frontier orbitals between the atoms that are not involved in the sigma bond formation.

The following can be explained by the diagram below

[[File:Kl MO interactions.jpg]]

From the above, we can see that there are more favorable orbital overlaps in the endo structure than in the case of the exo structure. In the endo structure, there are secondary orbital overlap which is absent in the exo structure. These interactions stabilises the molecule, and this is the primary reason why the endo structure is favoured over the exo structure as well as the steric factor mentioned above.

== Further Discussion ==

The vibrational mode of the transition state was studied to determine whether the reaction proceeds via synchronously or asynchronously.

[[File:Kl imag freq DA 3.gif]]

The vibrational mode shown above is very similar to the one of the Diels Alder reaction between ethene and butadiene, ie both reactants stretch towards each other in a concerted motion. Therefore the bond formation is synchronous.

File:Kl imag freq DA 3.gif

2014-03-21T13:23:27Z

Kwl11:

File:Kl MO interactions.jpg

2014-03-21T13:07:20Z

Kwl11:

File:Kl MO interaction Endo.jpg

2014-03-21T13:00:40Z

Kwl11:

File:Kl MO interaction Exo.jpg

2014-03-21T12:55:01Z

Kwl11:

Rep:Mod:PhyComp101292

2014-03-21T11:53:44Z

Kwl11:

Rep:Mod:PhyComp101292

2014-03-21T05:05:45Z

Kwl11:

= '''Cope Rearrangement''' =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; the effect of stabilising σC-H → σ*C-H and σC-C → σ*C-C orbital interactions, steric repulsions and The Van Der Wall's Forces. For n-butane, the energy levels of the donors and acceptors are all very similar since the electronegativity of all the atoms in the molecule are very similar so the 1st effect makes very little difference in deciding which conformation has a lower energy. Ethylene group is relatively big so steric strain is reduced when they are APP with respect to each other meaning that factor two favours the APP arrangement.

In the HF/3-21G basis set, gauche conformations are more stable than the APP ones but the reverse is observed in the B3LYP/6-31G* set. Based on the three factors explained above, we would expect expect the APP conformations to have lower energies than the gauche ones. This is because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the σC-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. This model is accurate enough to account for electronic correlation giving the expected result.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

<pre>Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png]]

<pre> Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.</pre>

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

== Optimisation of The Transition State by B3LYP/6-31G* ==

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gif|thumb|TS Mode of Vibration|centre|800px]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion so the bonds form synchronously where the atoms of both reactants are stretching vigously.

Compared to the first "Real" bending motion of the vibrational mode at 147 cm-1, the frequency corresponding to the TS vibrational mode is -956 cm-1 which is a lot higher in magnitude. This vibrational mode involves the stretching of both reactants which involves a lot more energy and hence a higher frequency than the simple bending motion in the first "Real" vibrational mode.

[[File:KlMode of 1st real vibration.gif|thumb|First Real Mode of Vibration|centre|800px]]

== Diels Alder Cycloaddition of Maleic Anhydride and Cyclohexadiene ==

Through this reaction, there are two possible transition states and this determines whether we get the exo or the endo product. Both the endo and exo transition state is optimised by Empirical/AM1 followed by B3LYP/6-31G*.

The log files can be found here: [[File:KL PART 3 DA exo (AM1).LOG]], [[File:kl Part 3 DA Endo (AM1).LOG]], [[File:KL PART 3 DA Exo 6-31G.LOG]], [[File:Kl Part 3 DA Endo (6-31G).LOG]]

The results are summarised below

{| class="wikitable" border="1"
|+ Exo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Exo (AM1) .jpg]] || [[File:Kl Exo (AM1) .jpg]]
|-
| Energy (a.u) || -0.05041966 || -612.67931094
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.17 || 2.29
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 2.94 || 3.03
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -812 || -449
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO35.jpg|200px|]] || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO34.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24216 || -0.07840
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

{| class="wikitable" border="1"
|+ Endo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Endo (AM1).jpg]] || [[File:Kl Endo (AM1).jpg]]
|-
| Energy (a.u) || -0.05150480 || -612.68339668
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.16 || 2.27
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 3.90 || 3.94
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -806 || -447
|}

The transition state was successfully optimised as the new sigma bond length between C2 and C8 and C5 and C7 are identical in both the Empirical/AM1 ( 2.16 A) and B3LYP/6-31G* (2.27 A) confirming that the new bonds are formed in a concerted manner. Furthermore, the presence of the imaginary frequency suggests that a energy maxima is achieved.

The endo and the exo structure differs by the orientation of the dienophile with respect to the diene. In the endo structure, the aldehyde is in the opposite phase with respect to the -CH2-Ch2- bridge whereas the aldehyde is in the same phase with the -CH2-Ch2- in the exo structure. From this point, we can see that the exo structure is sterically more hindered as there is a steric clash between the bridge and the aldehyde. This was illustrated in the B3LYP/6-31G* calculation where the distant between C3-C9/C4-C10 was 3.03 A in the exo structure and 3.94 A in the endo structure. Therefore the distant between the two groups are further apart in the endo structure making it energetically favoured due to less repulsion and hence lower in energy compared to the exo structure.

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]] || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24231 || -0.06773
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

The overlap between the HOMO of the Cyclohexa-1,3-diene and the LUMO of the aldehyde

File:Kl guessed TS chair parameters 3-21G.jpg

2014-03-21T04:44:41Z

Kwl11:

File:Kl allyl parameters.png

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Kwl11: uploaded a new version of "File:Kl allyl parameters.png"

File:Kl QST2 parameters 6-31G.png

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Kwl11: uploaded a new version of "File:Kl QST2 parameters 6-31G.png"

File:Kl QST2 parameters 6-31G.png

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Kwl11: uploaded a new version of "File:Kl QST2 parameters 6-31G.png"

File:Kl guessed TS chair parameters 6-31G.png

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Kwl11: uploaded a new version of "File:Kl guessed TS chair parameters 6-31G.png"

File:Kl guessed TS chair parameters 3-21G.png

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Kwl11: uploaded a new version of "File:Kl guessed TS chair parameters 3-21G.png"

File:Kl frozen coordinate parameters 6-31G.png

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Kwl11: uploaded a new version of "File:Kl frozen coordinate parameters 6-31G.png"

File:Kl frozen coordinate parameters 3-21G.png

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Kwl11: uploaded a new version of "File:Kl frozen coordinate parameters 3-21G.png"

File:Kl allyl parameters.png

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Kwl11: uploaded a new version of "File:Kl allyl parameters.png"

File:Kl Part 3 DA Endo (6-31G).LOG

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Kwl11:

File:KL PART 3 DA Exo 6-31G.LOG

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Kwl11:

File:Kl Part 3 DA Endo (AM1).LOG

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Kwl11:

File:KL PART 3 DA exo (AM1).LOG

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Kwl11:

Rep:Mod:PhyComp101292

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Kwl11:

= '''Cope Rearrangement''' =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; the effect of stabilising σC-H → σ*C-H and σC-C → σ*C-C orbital interactions, steric repulsions and The Van Der Wall's Forces. For n-butane, the energy levels of the donors and acceptors are all very similar since the electronegativity of all the atoms in the molecule are very similar so the 1st effect makes very little difference in deciding which conformation has a lower energy. Ethylene group is relatively big so steric strain is reduced when they are APP with respect to each other meaning that factor two favours the APP arrangement.

In the HF/3-21G basis set, gauche conformations are more stable than the APP ones but the reverse is observed in the B3LYP/6-31G* set. Based on the three factors explained above, we would expect expect the APP conformations to have lower energies than the gauche ones. This is because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the σC-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. This model is accurate enough to account for electronic correlation giving the expected result.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png]]

Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.
</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gifthumb|TS Mode of Vibration|centre|800px]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion so the bonds form synchronously where the atoms of both reactants are stretching vigously.

Compared to the first "Real" bending motion of the vibrational mode at 147 cm-1, the frequency corresponding to the TS vibrational mode is -956 cm-1 which is a lot higher in magnitude. This vibrational mode involves the stretching of both reactants which involves a lot more energy and hence a higher frequency than the simple bending motion in the first "Real" vibrational mode.

[[File:KlMode of 1st real vibration.gif|thumb|First Real Mode of Vibration|centre|800px]]

== Diels Alder Cycloaddition of Maleic Anhydride and Cyclohexadiene ==

Through this reaction, there are two possible transition states and this determines whether we get the exo or the endo product. Both the endo and exo transition state is optimised by Empirical/AM1 followed by B3LYP/6-31G*.

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Exo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Exo (AM1) .jpg]] || [[File:Kl Exo (AM1) .jpg]]
|-
| Energy (a.u) || -0.05041966 || -612.67931094
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.17 || 2.29
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 2.94 || 3.03
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -812 || -449
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO35.jpg|200px|]] || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO34.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24216 || -0.07840
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

{| class="wikitable" border="1"
|+ Endo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Endo (AM1).jpg]] || [[File:Kl Endo (AM1).jpg]]
|-
| Energy (a.u) || -0.05150480 || -612.68339668
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.16 || 2.27
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 3.90 || 3.94
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -806 || -447
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]] || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24231 || -0.06773
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

Rep:Mod:PhyComp101292

2014-03-21T02:13:35Z

Kwl11:

= '''Cope Rearrangement''' =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; the effect of stabilising σC-H → σ*C-H and σC-C → σ*C-C orbital interactions, steric repulsions and The Van Der Wall's Forces. For n-butane, the energy levels of the donors and acceptors are all very similar since the electronegativity of all the atoms in the molecule are very similar so the 1st effect makes very little difference in deciding which conformation has a lower energy. Ethylene group is relatively big so steric strain is reduced when they are APP with respect to each other meaning that factor two favours the APP arrangement.

In the HF/3-21G basis set, gauche conformations are more stable than the APP ones but the reverse is observed in the B3LYP/6-31G* set. Based on the three factors explained above, we would expect expect the APP conformations to have lower energies than the gauche ones. This is because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the σC-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. This model is accurate enough to account for electronic correlation giving the expected result.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png]]

Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.
</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gif]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion so the bonds form synchronously where the atoms of both reactants are stretching vigously.

Compared to the first "Real" bending motion of the vibrational mode at 147 cm-1, the frequency corresponding to the TS vibrational mode is -956 cm-1 which is a lot higher in magnitude. This vibrational mode involves the stretching of both reactants which involves a lot more energy and hence a higher frequency than the simple bending motion in the first "Real" vibrational mode.

[[File:KlMode of 1st real vibration.gif|thumb|First Real Mode of Vibration]]

== Diels Alder Cycloaddition of Maleic Anhydride and Cyclohexadiene ==

Through this reaction, there are two possible transition states and this determines whether we get the exo or the endo product. Both the endo and exo transition state is optimised by Empirical/AM1 followed by B3LYP/6-31G*.

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Exo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Exo (AM1) .jpg]] || [[File:Kl Exo (AM1) .jpg]]
|-
| Energy (a.u) || -0.05041966 || -612.67931094
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.17 || 2.29
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 2.94 || 3.03
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -812 || -449
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO35.jpg|200px|]] || [[File:KlMO34.jpg|200px|]]|| [[File:KlMO34.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24216 || -0.07840
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

{| class="wikitable" border="1"
|+ Endo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Endo (AM1).jpg]] || [[File:Kl Endo (AM1).jpg]]
|-
| Energy (a.u) || -0.05150480 || -612.68339668
|-
| Bond Length (C1-C2)/(C5-C6) || 1.39 || 1.39
|-
| Bond Length (C1-C6) || 1.40 || 1.40
|-
| Bond Length (C2-C8)/(C5-C7) || 2.16 || 2.27
|-
| Bond Length (C7-C8) || 1.41 || 1.39
|-
| Bond Length (C3-C9)/(C4-C10) || 3.90 || 3.94
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -806 || -447
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]] || [[File:KlMO 47.jpg|200px|]]|| [[File:KlMO 48.jpg|200px|]]
|-
| Energy Level || 34 || 35 || 47|| 48
|-
| Energy || -0.34273 || -0.04046 || -0.24231 || -0.06773
|-
| Symmetry With Respect to Plane || Asymmetric || Asymmetric || Asymmetric || Asymmetric
|}

File:KlMO 48.jpg

2014-03-21T02:11:28Z

Kwl11:

File:KlMO 47.jpg

2014-03-21T02:11:28Z

Kwl11:

File:KlMO35.jpg

2014-03-21T01:14:05Z

Kwl11:

File:KlMO34.jpg

2014-03-21T01:14:04Z

Kwl11:

Rep:Mod:PhyComp101292

2014-03-21T00:35:02Z

Kwl11:

= '''Cope Rearrangement''' =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; the effect of stabilising σC-H → σ*C-H and σC-C → σ*C-C orbital interactions, steric repulsions and The Van Der Wall's Forces. For n-butane, the energy levels of the donors and acceptors are all very similar since the electronegativity of all the atoms in the molecule are very similar so the 1st effect makes very little difference in deciding which conformation has a lower energy. Ethylene group is relatively big so steric strain is reduced when they are APP with respect to each other meaning that factor two favours the APP arrangement.

In the HF/3-21G basis set, gauche conformations are more stable than the APP ones but the reverse is observed in the B3LYP/6-31G* set. Based on the three factors explained above, we would expect expect the APP conformations to have lower energies than the gauche ones. This is because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the σC-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. This model is accurate enough to account for electronic correlation giving the expected result.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png]]

Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.
</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gif]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion so the bonds form synchronously where the atoms of both reactants are stretching vigously.

Compared to the first "Real" bending motion of the vibrational mode at 147 cm-1, the frequency corresponding to the TS vibrational mode is -956 cm-1 which is a lot higher in magnitude. This vibrational mode involves the stretching of both reactants which involves a lot more energy and hence a higher frequency than the simple bending motion in the first "Real" vibrational mode.

[[File:KlMode of 1st real vibration.gif|thumb|First Real Mode of Vibration]]

== Diels Alder Cycloaddition of Maleic Anhydride and Cyclohexadiene ==

Through this reaction, there are two possible transition states and this determines whether we get the exo or the endo product. Both the endo and exo transition state is optimised by Empirical/AM1 followed by B3LYP/6-31G*.

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Exo
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Structure || [[File:Kl Exo (AM1) .jpg]] || [[File:Kl Exo (AM1) .jpg]]
|-
| Energy (a.u) || -0.05041966 || -612.67931094
|-
| Bond Length || -0.05041966 || -612.67931094
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -812 || -449
|}

File:Kl Exo (AM1) .jpg

2014-03-21T00:13:31Z

Kwl11:

File:Kl Endo (AM1).jpg

2014-03-21T00:13:05Z

Kwl11:

File:KlMode of 1st real vibration.gif

2014-03-20T21:30:34Z

Kwl11:

Rep:Mod:PhyComp101292

2014-03-20T20:56:22Z

Kwl11:

= '''Cope Rearrangement''' =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; the effect of stabilising σC-H → σ*C-H and σC-C → σ*C-C orbital interactions, steric repulsions and The Van Der Wall's Forces. For n-butane, the energy levels of the donors and acceptors are all very similar since the electronegativity of all the atoms in the molecule are very similar so the 1st effect makes very little difference in deciding which conformation has a lower energy. Ethylene group is relatively big so steric strain is reduced when they are APP with respect to each other meaning that factor two favours the APP arrangement.

In the HF/3-21G basis set, gauche conformations are more stable than the APP ones but the reverse is observed in the B3LYP/6-31G* set. Based on the three factors explained above, we would expect expect the APP conformations to have lower energies than the gauche ones. This is because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the σC-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. This model is accurate enough to account for electronic correlation giving the expected result.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png]]

Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.
</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg|200px]]|| [[File:Kl MO12.jpg|200px]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

The log files can be found here [[File:KlSEMIempirical.LOG]], [[File:Kl_6-31G_DA_part_2.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ Results
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|}

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO(AM1) !! LUMO(AM1) !! HOMO(6-31G*) !! LUMO(6-31G*)
|-
| Structure || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]] || [[File:KlMO17.jpg|200px|]]|| [[File:KlMO18.jpg|200px|]]
|-
| Energy Level || 17 || 18 || 23|| 24
|-
| Energy || -0.32393 || 0.02315 || -0.21895 || -0.00861
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric || Assymmetric || Symmetric
|}

From the above table, it is clear that the partially formed sigma bonds are shorter than 2x VDW radius of the sp2 carbon atoms (3.4 A) but longer than the covalent bond between the sp2 carbon atoms. This means that the formation of the new sigma bonds between Cis 1,3-Butadiene and ethene was successful suggesting that the predicted transition state is correct.

The HOMO of the TS is anti-symmetric with respect to the plane, this is understandable as this orbital is formed from the HOMO of butadiene and the LUMO of ethylene which are both anti-symmetric. Additionally, there are notable amount of electron density about where the new sigma bonds formed. Therefore, this reaction is allowed by the Woodward-Hoffmann rule.

The animation below shows how the new bonds are formed

[[File:KlMode of Formation of new bond.gif]]

This is the vibrational mode of the imaginary frequency based on the Empirical/AM1 calculation. The terminal carbon atoms of the 1,3-Cis Butadiene and ethylene approaches each other in a concerted fashion where the atoms of both reactants are stretching vigously to form the new bonds.

File:KlMode of Formation of new bond.gif

2014-03-20T20:35:06Z

Kwl11:

File:Kl 6-31G DA part 2.LOG

2014-03-20T19:47:16Z

Kwl11:

Rep:Mod:PhyComp101292

2014-03-20T18:48:01Z

Kwl11:

= '''Cope Rearrangement''' =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; the effect of stabilising σC-H → σ*C-H and σC-C → σ*C-C orbital interactions, steric repulsions and The Van Der Wall's Forces. For n-butane, the energy levels of the donors and acceptors are all very similar since the electronegativity of all the atoms in the molecule are very similar so the 1st effect makes very little difference in deciding which conformation has a lower energy. Ethylene group is relatively big so steric strain is reduced when they are APP with respect to each other meaning that factor two favours the APP arrangement.

In the HF/3-21G basis set, gauche conformations are more stable than the APP ones but the reverse is observed in the B3LYP/6-31G* set. Based on the three factors explained above, we would expect expect the APP conformations to have lower energies than the gauche ones. This is because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the σC-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. This model is accurate enough to account for electronic correlation giving the expected result.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png]]

Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.
</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg]]|| [[File:Kl MO12.jpg]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ MO Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg]]|| [[File:Kl MO12.jpg]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of Transition State of The DA Reaction Between Ethene and Butadiene ==

[[File:KlDA_of_Butadiene_and_Ethene.jpg|thumb|Transition State]]

The distant between the two terminal carbon atoms was guessed to be 2A. The above was initially optimised using Semi-empirical/Am1 and then re-optimised with B3LYP/6-31G*. The HOMO and LUMO was plotted to identify the symmetry and the orbital overlapping of the frontier orbitals during the transition state.

== Semi-empirical/AM1 ==

The log file for this calculation can be found here [[File:KlSEMIempirical.LOG]]

The results are summarised in the table below

{| class="wikitable" border="1"
|+ MO Analysis
! !! Semi-empirical/AM1 !! B3LYP/6-31G*
|-
| Length Between Terminal ends || 2.12 || 2.27
|-
| Energy (a.u) || 0.11165468 || -234.54389654
|-
| Point Group || C1 || C1
|-
| Imaginary Frequency || -956 || -525
|-
| Log File || Assymmetric || Symmetric
|}

File:KlMO18.jpg

2014-03-20T18:10:28Z

Kwl11:

File:KlMO17.jpg

2014-03-20T18:10:27Z

Kwl11:

File:Klsemiempiricalparameters.jpg

2014-03-20T18:10:27Z

Kwl11:

File:KlSEMIempirical.LOG

2014-03-20T18:10:26Z

Kwl11: uploaded a new version of "File:KlSEMIempirical.LOG"

File:KlSEMIempirical.LOG

2014-03-20T17:42:19Z

Kwl11:

File:KlDA of Butadiene and Ethene.jpg

2014-03-20T16:17:14Z

Kwl11:

Rep:Mod:PhyComp101292

2014-03-20T15:57:55Z

Kwl11:

= '''Cope Rearrangement''' =

== '''Introduction''' ==

[3,3]-sigmatropic shift rearrangement has been the subject of numerous experimental and computational studies. For many years, the actual mechanism was debated; the reaction can proceed in a concerted, dissociative or stepwise manner. Today, evidences suggest that the reaction proceeds in a concerted manner via a “chair” or a “boat” transition state where the “chair” transition state lies few kJmol-1 lower in energy.
In this exercise, the B3LYP/6-31G model will be employed to optimise the structure of both transition states. The activation energy of both pathways will be computed to determine the preferred mechanism of the Cope rearrangement and see if the result agrees well with the literature. The reaction scheme is summarised in the scheme below

[[File:Kl_Cope_Scheme.jpg]]

== '''Aim''' ==

By rotating the central C-C sigma bond, different conformers of 1,5-hexadiene can be generated. We start off by optimising the conformation with the two substituents anti-periplanar with respect to each other. The optimisation process was done using the HF/3-21 G basis-set and then the structure will be re-optimised using the more accurate B3LYP/6-31G* basis-set. Other conformations with the substituents occupying different positions will also be studied.

== '''Optimisation via Hartree/3-21 G)''' ==

=== '''Optimisation of 1,5-hexadiene (Anti 1)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 1).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 1.jpg|400px|left|]]

The most important information is the gradient since the derivative of energy is force. If the gradient is 0 then there is no net force acting on the molecule and the molecule is at a stable minimum point. The value of the gradient in this case is very close to 0 suggesting that the minimum point was identified and the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000055 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000379 0.001800 YES
RMS Displacement 0.000158 0.001200 YES
Predicted change in Energy=-1.526246D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Anti 2)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(ANTI_2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (ANTI 2).LOG]]

The settings and results are shown below

[[File:KlParameters Anti 2.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000060 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.000516 0.001800 YES
RMS Displacement 0.000171 0.001200 YES
Predicted change in Energy=-2.037087D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 3)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(Gauch_3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (Gauch 3).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 3.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000044 0.000450 YES
RMS Force 0.000009 0.000300 YES
Maximum Displacement 0.001476 0.001800 YES
RMS Displacement 0.000493 0.001200 YES
Predicted change in Energy=-3.610722D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

=== '''Optimisation of 1,5-hexadiene (Gauche 4)''' ===

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎KlOPTIMISATION_OF_HEXADIENE_(GAUCH_4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The log file for this calculation can be found here [[File:KlOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]]

The settings and results are shown below

[[File:KlParameters Gauche 4.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000018 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000800 0.001800 YES
RMS Displacement 0.000331 0.001200 YES
Predicted change in Energy=-1.009941D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

== '''Optimisation + Frequency Analysis via B3LYP/6-31G*)''' ==

B3LYP/6-31G* is a much better basis set and provides more accurate results despite longer calculation time compared to HF/3-21G. Frequency analysis is carried out to confirm that the optimised structure is at the minimum point of the potential surface. Although the gradient in the optimisation calculation is very close to 0,it just means the molecule is at a turning point, it can either be a maximum or a minimum. We need to consider the 2nd derivative of the potential surface to confirm that the turning point is a minimum. The 2nd derivative of potential surface is effectively the frequency, hence if the frequency is negative then the turning point is a maximum (transition state) and if it is positive then it is a minimum point. Frequency analysis also allows us to determine whether the frequencies are real ie within the range of ±15cm-1 as well as providing Thermochemistry and IR spectrocopic data.

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 1)''' ===

The log files can be found here: [[File:Kl 6-31G OPTIMISATION OF HEXADIENE (ANTI 1).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 1).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 1 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 1 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000012 0.000450 YES
RMS Force 0.000005 0.000300 YES
Maximum Displacement 0.000160 0.001800 YES
RMS Displacement 0.000067 0.001200 YES
Predicted change in Energy=-9.063092D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -6.5500 -3.2145 -0.0007 0.0006 0.0008 3.3524
Low frequencies --- 74.1783 98.0287 113.7145

Sum of electronic and zero-point Energies= -234.469305
Sum of electronic and thermal Energies= -234.461974
Sum of electronic and thermal Enthalpies= -234.461030
Sum of electronic and thermal Free Energies= -234.500220

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Anti 2)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 2).LOG]] and
[[File:KlFrequency analysis of hexadiene (ANTI 2).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Anti 2 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Anti 2 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000015 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000219 0.001800 YES
RMS Displacement 0.000079 0.001200 YES
Predicted change in Energy=-1.588865D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -7.6846 -2.7154 -0.0008 0.0003 0.0006 1.6605
Low frequencies --- 73.5514 80.5643 121.0103

Sum of electronic and zero-point Energies= -234.469219
Sum of electronic and thermal Energies= -234.461869
Sum of electronic and thermal Enthalpies= -234.460925
Sum of electronic and thermal Free Energies= -234.500808

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 3)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 3).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>‎Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 3 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 3 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000006 0.000450 YES
RMS Force 0.000002 0.000300 YES
Maximum Displacement 0.000530 0.001800 YES
RMS Displacement 0.000133 0.001200 YES
Predicted change in Energy=-1.487598D-09
Optimization completed.
-- Stationary point found.
</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -0.0006 -0.0004 0.0003 2.1011 3.5412 6.4601
Low frequencies --- 73.5488 100.9878 123.9092

Sum of electronic and zero-point Energies= -234.468719
Sum of electronic and thermal Energies= -234.461477
Sum of electronic and thermal Enthalpies= -234.460533
Sum of electronic and thermal Free Energies= -234.500173

=== '''Optimisation + Frequency Analysis of 1,5-hexadiene (Gauche 4)''' ===

The log files can be found here: [[File:Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).LOG]] and [[File:KlFrequency analysis of hexadiene (GAUCH 4).LOG]]

The 3D Structure can be seen here <jmol>
<jmolAppletButton>
<uploadedFileContents>Kl 6-31GOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 4</text>
</jmolAppletButton>
</jmol>

The settings and results are shown below

[[File:KlParameters Gauche 4 (6-31G(d)).jpg|400px|left|]] [[File:KlParameters Gauche 4 freq.jpg|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000004 0.000300 YES
Maximum Displacement 0.000701 0.001800 YES
RMS Displacement 0.000231 0.001200 YES
Predicted change in Energy=-5.277948D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

There are no imaginary frequencies

Low frequencies --- -2.8305 -0.0010 -0.0006 -0.0003 3.9521 5.0823
Low frequencies --- 65.6750 101.7133 108.1475

Sum of electronic and zero-point Energies= -234.468244
Sum of electronic and thermal Energies= -234.460957
Sum of electronic and thermal Enthalpies= -234.460013
Sum of electronic and thermal Free Energies= -234.499226

== '''Summary ''' ==

{| class="wikitable" border="1"
|+ Table 1
! Structure !! Energy 3-21G (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Energy 6-31G* (Hartree) !! Relative Energy to Gauche 3 (kCal/mol)!! Sum of electronic and zero-point Energies (Hartree) !! Sum of electronic and thermal Energies (Hartree) !! Sum of electronic and thermal Enthalpies (Hartree) !! Sum of electronic and thermal Free Energies (Hartree) !! Point Group
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 1).mol2</uploadedFileContents>
<text>APP 1</text>
</jmolAppletButton>
</jmol> || -231.69260235 || 0.04 || -234.61180037 || 0.30 || -234.469305 || -234.461974 || -234.461030 || -234.500220 || C2
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (ANTI 2).mol2</uploadedFileContents>
<text>APP 2</text>
</jmolAppletButton>
</jmol> || -231.69253528 || 0.08 || -234.61170280 || 0.23 || -234.469219 || -234.461869 || -234.460925 || -234.500808 || Ci
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (Gauch 3).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69266120 || 0.00 || -234.61132934 || 0.00 || -234.468719 || -234.461477 || -234.460533 || -234.500173 || C1
|-
| <jmol>
<jmolAppletButton>
<uploadedFileContents>KlOPTIMISATION OF HEXADIENE (GAUCH 4).mol2</uploadedFileContents>
<text>Gauche 3</text>
</jmolAppletButton>
</jmol> || -231.69166701 || 0.62 || -234.61070764 || 0.39 || -234.468244 || -234.460957 || -234.460013 || -234.499226 || C2
|}

Based on the information above, it can be seen that both HF/3-21G and B3LYP/6-31G* basis-set leads to the same structure for a particular conformer.

The conformation with the lowest energy is Gauche 3, hence this is the most stable conformer of 1,5-hexadiene.

The relative stabilities of the gauche and app conformations is governed by three main factors; the effect of stabilising σC-H → σ*C-H and σC-C → σ*C-C orbital interactions, steric repulsions and The Van Der Wall's Forces. For n-butane, the energy levels of the donors and acceptors are all very similar since the electronegativity of all the atoms in the molecule are very similar so the 1st effect makes very little difference in deciding which conformation has a lower energy. Ethylene group is relatively big so steric strain is reduced when they are APP with respect to each other meaning that factor two favours the APP arrangement.

In the HF/3-21G basis set, gauche conformations are more stable than the APP ones but the reverse is observed in the B3LYP/6-31G* set. Based on the three factors explained above, we would expect expect the APP conformations to have lower energies than the gauche ones. This is because HF/3-21G basis set is too simple to account for electronic correlations and as a result, the stabilisation effect due to the σC-C→π* is overestimated and outweighing the steric clash between the two bulky substituents and hence favouring the gauche conformations.

In the B3LYP/6-31G* basis-set, the APP conformations are favoured as expected for the reason stated above, namely that the two substituents are as far apart as possible meaning that steric repulsion is minimised. This model is accurate enough to account for electronic correlation giving the expected result.

== Optimisation of The Transition State (HF/3-21G) ==

There are various methods to optimise a transition state and each of these will be demonstrated.

=== Optimisation of The Allyl Fragment ===

This calculation is required to generate the structure of the transition state. The log file can be found here [[File:KlOPTIMISATION OF ALLYL FRAQMENT.LOG]].

The setting and result are as follow:

[[File:Kl allyl parameters.png|400px|left|]]

Item Value Threshold Converged?
Maximum Force 0.000153 0.000450 YES
RMS Force 0.000077 0.000300 YES
Maximum Displacement 0.001150 0.001800 YES
RMS Displacement 0.000603 0.001200 YES
Predicted change in Energy=-4.449593D-07
Optimization completed.
-- Stationary point found.

Based on the information above, the convergence was successful.

=== Optimisation of The Transition State by Computing the Force Constant ===

Two lots of the optimised fragment was copied to a new Gaussview window. Both terminal ends of the two fragments was set to 2.2 A apart from each other. The optimisation was carried out and the log file can be found here [[File:Kl GUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000037 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.001118 0.001800 YES
RMS Displacement 0.000234 0.001200 YES
Predicted change in Energy=-8.125308D-08
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -818.0169 -3.4046 -0.0009 -0.0007 -0.0004 2.5837
Low frequencies --- 3.2377 209.5117 395.8642

Sum of electronic and zero-point Energies= -231.466701
Sum of electronic and thermal Energies= -231.461341
Sum of electronic and thermal Enthalpies= -231.460397
Sum of electronic and thermal Free Energies= -231.495207

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:KlCHAIR_TS_(FROZEN_COORDINATE_METHOD_PART_D).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 3-21G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000074 0.000450 YES
RMS Force 0.000022 0.000300 YES
Maximum Displacement 0.001548 0.001800 YES
RMS Displacement 0.000392 0.001200 YES
Predicted change in Energy=-1.931135D-07
Optimization completed.
-- Stationary point found.</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-818 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -817.8731 -0.0005 -0.0001 0.0003 0.5560 5.5385
Low frequencies --- 8.2496 209.6239 395.9590

Sum of electronic and zero-point Energies= -231.466704
Sum of electronic and thermal Energies= -231.461345
Sum of electronic and thermal Enthalpies= -231.460401
Sum of electronic and thermal Free Energies= -231.495211

=== Optimisation of The Transition State by QST2 ===

Unlike the first two methods where we actually build the transition state, this method predicts the transition state by interpolating between the structure of the reactant and product. Therefore the atom label between the reactant and product must corresponds to each other just like the case shown below.

[[File:KlQ2T2 Numbering.jpg]]

The above was optimised using QST2 setting and the log file for this calculation can be found here [[File:FIRST_QST2_CAL.LOG]]

The optimisation was not successful, the structure is similar to the chair transition structure but more dissociated. During the imterpolation between the two structures, the top allyl fragment was simply translated and the possibility of a rotation around the central bonds was not considered at all. If we start with these structures of the product and reactant, it is clear that the boat transition state will never be located. Therefore the structures of the product and reactant must resemble the boat transtion state so the structures were changed as follow

[[File:KlQ2T2 Adjustment.jpg]]

The log file for this calculation can be found here. [[File:KlFIRST QST2 CAL.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 3-21G.png]]

Item Value Threshold Converged?
Maximum Force 0.000067 0.000450 YES
RMS Force 0.000015 0.000300 YES
Maximum Displacement 0.001391 0.001800 YES
RMS Displacement 0.000353 0.001200 YES
Predicted change in Energy=-1.075013D-07
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-840 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -840.1921 -1.6525 0.0006 0.0008 0.0008 3.0246
Low frequencies --- 5.5986 155.3989 382.1404

Sum of electronic and zero-point Energies= -231.450928
Sum of electronic and thermal Energies= -231.445300
Sum of electronic and thermal Enthalpies= -231.444356
Sum of electronic and thermal Free Energies= -231.479772

== Intrinsic Reaction Coordinate ==

IRC is important as it tells us which conformers of 1,5-hexadiene connects, it allow us to follow the minimum energy path from a transition structure down to its local minimum on a potential energy surface. Without this technique it is very difficult to predict which conformer the reaction paths from the transitions structures will lead to. IRC will be demonstrated on the HF/3-21G optimised chair conformation to locate its transition state.

{| class="wikitable" border="1"
|+ IRC Analysis
! !! Energy !! Dihedral Angle !! Structure !! Point Group !! IRC plot !! Log file
|-
| Initial IRC || -231.69157923|| 67.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED TS CHAIR.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 ||[[File:KlIRC plot 50 steps.png|600px|]] ||[[File: Kl_IRC.LOG]]
|-
| Further IRC || -231.69166702 ||64.2 || <jmol><jmolApplet>
<title>test molecule</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>KlGUESSED_TS_CHAIR_More_IRC.mol2</uploadedFileContents>
</jmolApplet></jmol> || C2 || [[File:KlFurther IRC plot.png|600px|]] || [[File:Kl_IRC2.LOG]]
|
|}

In the first run, the number of points along the IRC was set to 50. From the structure, it is clear that the transition state is not reached as its energy nor structure does not corresponds to any of the conformers listed in Appendix 1 despite the fact that the IRC plot tends towards a stationary point near the end of the calculation. Hence the last point of the IRC path was optimised using HF/3-21 G to proceed further. From the graph of this optimisation process, the energy still decreases reinforcing the fact that the minimum point was not reached initially. The result suggests that the optimisation was successful since it is converged.

Item Value Threshold Converged?
Maximum Force 0.000010 0.000450 YES
RMS Force 0.000003 0.000300 YES
Maximum Displacement 0.000298 0.001800 YES
RMS Displacement 0.000091 0.001200 YES
Predicted change in Energy=-2.405357D-09
Optimization completed.
-- Stationary point found.

The energy of the optimised structure matches exactly with the one of Gauche 2 in Appendix 1.Therefore the IRC method suggests that Gauche 2 is the conformer of 1,5-hexadiene that leads to the chair transition state structure in the Cope Rearrangement of 1,5-hexadiene.

=== Optimisation of The Transition State by Computing the Force Constant ===

The optimisation was carried out and the log file can be found here [[File:KlGUESSED TS CHAIR.LOG]]

The settings and results was as follow

[[File:Kl guessed TS chair parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre>Item Value Threshold Converged?
Maximum Force 0.000023 0.000450 YES
RMS Force 0.000006 0.000300 YES
Maximum Displacement 0.000085 0.001800 YES
RMS Displacement 0.000027 0.001200 YES
Predicted change in Energy=-4.040758D-09
Optimization completed.
-- Stationary point found.</pre>

From the table above, the forces were converged and this reinforces the fact that the optimisation was successful.

The most important imaginary frequency (-566 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.6435 -0.0007 -0.0006 0.0003 22.0004 27.2717
Low frequencies --- 39.5182 194.6021 267.8645

Sum of electronic and zero-point Energies= -234.414929
Sum of electronic and thermal Energies= -234.409008
Sum of electronic and thermal Enthalpies= -234.408064
Sum of electronic and thermal Free Energies= -234.443159

=== Optimisation of The Transition State Via Redundant coordinate editor ===

The log file for this calculation can be found here [[File:Kl6-31GdCHAIR_TS_(FROZEN_COORDINATE_METHOD).LOG‎]]

The settings and results was as follow

[[File:Kl frozen coordinate parameters 6-31G.png|400px|left|]]

The value of the gradient is very close to 0 suggesting that the optimisation was successful.

<pre> Item Value Threshold Converged?
Maximum Force 0.000029 0.000450 YES
RMS Force 0.000010 0.000300 YES
Maximum Displacement 0.001111 0.001800 YES
RMS Displacement 0.000419 0.001200 YES
Predicted change in Energy=-1.749175D-07
Optimization completed.
-- Stationary point found.
</pre>

Based on the information above, the minimisation was successful.

The most important imaginary frequency (-565 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -565.3598 -0.0008 0.0003 0.0006 21.5705 27.1004
Low frequencies --- 39.2434 194.4948 268.2299

Sum of electronic and zero-point Energies= -234.414923
Sum of electronic and thermal Energies= -234.409004
Sum of electronic and thermal Enthalpies= -234.408059
Sum of electronic and thermal Free Energies= -234.443153

=== Optimisation of The Transition State by QST2 ===

The atom label between the reactant and product corresponds to each other.

[[File:KlQ2T2 Adjustment.jpg]]

The above was optimised using B3LYP3/6-31G* QST2 setting and the log file for this calculation can be found here [[File:FIRST QST2 CAL 6-31G.LOG]]

The settings and results were as follow

[[File:Kl QST2 parameters 6-31G.png]]

Item Value Threshold Converged?
Maximum Force 0.000051 0.000450 YES
RMS Force 0.000012 0.000300 YES
Maximum Displacement 0.000824 0.001800 YES
RMS Displacement 0.000217 0.001200 YES
Predicted change in Energy=-4.980745D-08
Optimization completed.
-- Stationary point found.

Base on the above information the convergence is now successful.

The most important imaginary frequency (-530 cm-1) is present and this suggests that the transition state is reached.

Low frequencies --- -530.0304 -9.4662 -0.0006 -0.0006 -0.0005 15.4582
Low frequencies --- 17.6698 135.5764 261.5656

Sum of electronic and zero-point Energies= -234.402344
Sum of electronic and thermal Energies= -234.396008
Sum of electronic and thermal Enthalpies= -234.395064
Sum of electronic and thermal Free Energies= -234.431755

= '''Diels Alder Reaction''' =

== Optimisation of 1,3-Cis Butadiene (Empirical/AM1) ==

The log file for this calculation can be found here [[File:KlOPT BUTADIENE (SEMI EMPIRICAL).LOG]]

The settings and results were as follow

[[File:KlButadiene parameters.jpg]]

Item Value Threshold Converged?
Maximum Force 0.000030 0.000450 YES
RMS Force 0.000011 0.000300 YES
Maximum Displacement 0.000407 0.001800 YES
RMS Displacement 0.000162 0.001200 YES
Predicted change in Energy=-9.691189D-09
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ IRC Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg]]|| [[File:Kl MO12.jpg]]
|-
| Energy Level || 11 || 12
|-
| Energy || -0.34381 || 0.01707
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

== Optimisation of 1,3-Cis Butadiene (B3LYP/6-31G*) ==

The log file for this calculation can be found here [[File:KlOPT_BUTADIENE_(6-31G).LOG]]

The settings and results were as follow

[[File:KlOPT_BUTADIENE_(6-31G).LOG]]

Item Value Threshold Converged?
Item Value Threshold Converged?
Maximum Force 0.000090 0.000450 YES
RMS Force 0.000035 0.000300 YES
Maximum Displacement 0.000427 0.001800 YES
RMS Displacement 0.000156 0.001200 YES
Predicted change in Energy=-5.870266D-08
Optimization completed.
-- Stationary point found.

Base on the above the optimisation was successful

{| class="wikitable" border="1"
|+ IRC Analysis
! MO !! HOMO !! LUMO
|-
| Structure || [[File:KlMO11.jpg]]|| [[File:Kl MO12.jpg]]
|-
| Energy Level || 15 || 16
|-
| Energy || -0.32141 || 0.12345
|-
| Symmetry With Respect to Plane || Assymmetric || Symmetric
|}

File:KlOPT BUTADIENE (6-31G).LOG

2014-03-20T15:49:05Z

Kwl11:

File:Kl6-31GOPT BUTADIENE (SEMI EMPIRICAL).LOG

2014-03-20T04:13:24Z

Kwl11: