ChemWiki - User contributions [en]

Intro to Molecular Modelling 2 ASG17

2018-03-02T14:30:06Z

Asg17: /* IMAGE */

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_O2_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.16160
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

[[File:O2_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies for O2.]]
As oxygen is a linear molecule you would expect it to have 3N-5 normal vibrational modes where N = 2, as there are two atoms. This indicates that oxygen has 1 vibrational mode, as shown by the image.

=== CHARGE ANALYSIS ===

[[File:O2_Charge_Analysis.png|thumb|left|Charges on Each Atom for O2.]]
The image shows the charges on each oxygen atom in a molecule of oxygen. As they are two of the same atom, there is no difference in electronegativity meaning that overall the molecule has no charge.

=== MOLECULAR ORBITALS ===

[[File:O2_Molecular_Orbitals.png|thumb|left|Molecular Orbitals for O2. ]]

The image on the left shows the molecular orbitals for a molecule of oxygen. Due to both atoms having the same electronegativty and the way in which the atoms are bonded to each other, this is how the molecular orbitals appear.

Intro to Molecular Modelling 2 ASG17

2018-03-02T14:25:45Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.16160
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

[[File:O2_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies for O2.]]
As oxygen is a linear molecule you would expect it to have 3N-5 normal vibrational modes where N = 2, as there are two atoms. This indicates that oxygen has 1 vibrational mode, as shown by the image.

=== CHARGE ANALYSIS ===

[[File:O2_Charge_Analysis.png|thumb|left|Charges on Each Atom for O2.]]
The image shows the charges on each oxygen atom in a molecule of oxygen. As they are two of the same atom, there is no difference in electronegativity meaning that overall the molecule has no charge.

=== MOLECULAR ORBITALS ===

[[File:O2_Molecular_Orbitals.png|thumb|left|Molecular Orbitals for O2. ]]

The image on the left shows the molecular orbitals for a molecule of oxygen. Due to both atoms having the same electronegativty and the way in which the atoms are bonded to each other, this is how the molecular orbitals appear.

Intro to Molecular Modelling 2 ASG17

2018-03-02T14:25:26Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.16160
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

[[File:O2_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies for O2.]]
As oxygen is a linear molecule you would expect it to have 3N-5 normal vibrational modes where N = 2, as there are two atoms. This indicates that oxygen has 1 vibrational mode, as shown by the image.

=== CHARGE ANALYSIS ===

[[File:O2_Charge_Analysis.png|thumb|left|Charges on Each Atom for O2.]]
The image shows the charges on each oxygen atom in a molecule of oxygen. As they are two of the same atom, there is no difference in electronegativity meaning that overall the molecule has no charge.

=== MOLECULAR ORBITALS ===

[[File:O2_Molecular_Orbitals.png|thumb|left|Molecular Orbitals for O2. ]]

The image on the left shows the molecular orbitals for a molecule of oxygen. Due to both atoms having the same electronegativty and the way in which the atoms are bonded to each other, this is how the molecular orbitals appear.

File:O2 Vibrational Frequencies.png

2018-03-02T14:23:47Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T14:23:29Z

Asg17: /* VIBRATIONS */

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.16160
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

[[File:O2_Vibrational_Frequencies.png]]

=== CHARGE ANALYSIS ===

[[File:O2_Charge_Analysis.png|thumb|left|Charges on Each Atom for O2.]]
The image shows the charges on each oxygen atom in a molecule of oxygen. As they are two of the same atom, there is no difference in electronegativity meaning that overall the molecule has no charge.

=== MOLECULAR ORBITALS ===

[[File:O2_Molecular_Orbitals.png|thumb|left|Molecular Orbitals for O2. ]]

The image on the left shows the molecular orbitals for a molecule of oxygen. Due to both atoms having the same electronegativty and the way in which the atoms are bonded to each other, this is how the molecular orbitals appear.

Intro to Molecular Modelling 2 ASG17

2018-03-02T14:21:36Z

Asg17: /* MOLECULAR ORBITALS */

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.16160
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

=== CHARGE ANALYSIS ===

[[File:O2_Charge_Analysis.png|thumb|left|Charges on Each Atom for O2.]]
The image shows the charges on each oxygen atom in a molecule of oxygen. As they are two of the same atom, there is no difference in electronegativity meaning that overall the molecule has no charge.

=== MOLECULAR ORBITALS ===

[[File:O2_Molecular_Orbitals.png|thumb|left|Molecular Orbitals for O2. ]]

The image on the left shows the molecular orbitals for a molecule of oxygen. Due to both atoms having the same electronegativty and the way in which the atoms are bonded to each other, this is how the molecular orbitals appear.

File:O2 Molecular Orbitals.png

2018-03-02T14:19:43Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T14:19:26Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.16160
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

=== CHARGE ANALYSIS ===

[[File:O2_Charge_Analysis.png|thumb|left|Charges on Each Atom for O2.]]
The image shows the charges on each oxygen atom in a molecule of oxygen. As they are two of the same atom, there is no difference in electronegativity meaning that overall the molecule has no charge.

=== MOLECULAR ORBITALS ===

[[File:O2_Molecular_Orbitals.png|thumb|left|Molecular Orbitals for O2. ]]

Intro to Molecular Modelling 2 ASG17

2018-03-02T14:13:15Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.16160
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

=== CHARGE ANALYSIS ===

[[File:O2_Charge_Analysis.png|thumb|left|Charges on Each Atom for O2.]]
The image shows the charges on each oxygen atom in a molecule of oxygen. As they are two of the same atom, there is no difference in electronegativity meaning that overall the molecule has no charge.

=== MOLECULAR ORBITALS ===

Intro to Molecular Modelling 2 ASG17

2018-03-02T14:12:19Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.16160
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

=== CHARGE ANALYSIS ===

[[File:O2_Charge_Analysis.png|thumb|left|]]
The image shows the charges on each oxygen atom in a moolecuole of oxygen. As they are two of the same atom, there is no difference in electronegativity meaning that overall the molecule has no charge.

=== MOLECULAR ORBITALS ===

File:O2 Charge Analysis.png

2018-03-02T14:11:37Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T14:11:21Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.16160
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

=== CHARGE ANALYSIS ===

[[File:O2_Charge_Analysis.png]]
The image shows the charges on each oxygen atom in a moolecuole of oxygen. As they are two of the same atom, there is no difference in electronegativity meaning that overall the molecule has no charge.

=== MOLECULAR ORBITALS ===

Intro to Molecular Modelling 2 ASG17

2018-03-02T14:02:38Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.16160
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

=== CHARGE ANALYSIS ===

=== MOLECULAR ORBITALS ===

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:53:05Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.01798
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

=== VIBRATIONS ===

=== CHARGE ANALYSIS ===

=== MOLECULAR ORBITALS ===

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:48:32Z

Asg17: /* Optimised Parameters */

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.01798
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for O2.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:48:09Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.01798
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for 02.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:47:49Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.01798
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for 02.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for O2.]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for O2.]]

File:O2 RMS Gradient Norm Optimisation.png

2018-03-02T13:46:07Z

Asg17:

File:O2 Total Energy Graph Optimisation.png

2018-03-02T13:45:48Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:45:33Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters for an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, NH3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.01798
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for 02.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of oxygen, O2.

[[File:O2_Total_Energy_Graph_Optimisation.png]]

The following image is a graph showing the RMS gradient at each stage of optimisation.

[[File:O2_RMS_Gradient_Norm_Optimisation.png]]

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:38:44Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.01798
|-
|}

==== Optimised Parameters ====

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for 02.]]

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:38:07Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.01798
|-
|}

[[File:O2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for 02.]]

File:O2 Final Set of Optimised Parameters.png

2018-03-02T13:35:46Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:35:16Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.01798
|-
|}

[[File:O2_Final_Set_of_Optimised_Parameters.png]]

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:30:29Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - O2</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>asg17_o2_opt_pop.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMISATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of O2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -150.25250603
|-
| RMS Gradient || 0.05905207
|-
| Point Group || D*H
|-
| Bond Distance || 1.01798
|-
|}

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:20:33Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_O2_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:19:58Z

Asg17:

== NH3 ==

=== IMAGE ===

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

[[File:ASG17_O2_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_O2_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:19:03Z

Asg17:

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====

[[File:H2_Molecular_Orbitals.png|thumb|left|H2 Molecular Orbitals.]]

==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

==== NH3 ====
[[File:NH3_Molecular_Orbitals.png|thumb|left|NH3 Molecular Orbitals.]]

== Molecule of Own Choice - O2 ==

=== IMAGE ===

[[File:ASG17_O2_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_O2_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:11:17Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:11:03Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:10:48Z

Asg17:

File:NH3 Molecular Orbitals.png

2018-03-02T13:08:18Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:08:02Z

Asg17:

File:H2 Molecular Orbitals.png

2018-03-02T13:05:08Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T13:04:51Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:56:28Z

Asg17:

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====
==== N2 ====

[[File:N2_Molecular_Orbitals.png|thumb|left|N2 Molecular Orbitals.]]

File:N2 Molecular Orbitals.png

2018-03-02T12:55:26Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:55:10Z

Asg17:

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-109.52412868
|-
| RMS Gradient || 0.00000060
|-
| Point Group || D*H
|-
| Bond Distance || 1.10550
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

=== MOLECULAR ORBITALS ===

==== H2 ====
==== N2 ====

[[File:N2_Molecular_Orbitals.png]]

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:36:31Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:33:50Z

Asg17:

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for N2.]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

File:N2 Final Set of Optimised Parameters.png

2018-03-02T12:32:41Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:32:26Z

Asg17:

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:N2_Final_Set_of_Optimised_Parameters.png]]

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:28:32Z

Asg17:

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

==== Calculations ====

E(NH3)= -56.55776873

2*E(NH3)= -113.11553746

E(N2)= -109.52412868

E(H2)= -1.15928020

3*E(H2)= -3.4778406

ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:24:45Z

Asg17:

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== N2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of N2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

==== Calculations ====

E(NH3)= -56.55776873
2*E(NH3)= -113.11553746
E(N2)= -109.52412868
E(H2)= -1.15928020
3*E(H2)= -3.4778406
ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:24:00Z

Asg17:

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== Calculations ====

E(NH3)= -56.55776873
2*E(NH3)= -113.11553746
E(N2)= -109.52412868
E(H2)= -1.15928020
3*E(H2)= -3.4778406
ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:23:44Z

Asg17:

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== Calculations ====

E(NH3)= -56.55776873
2*E(NH3)= -113.11553746
E(N2)= -109.52412868
E(H2)= -1.15928020
3*E(H2)= -3.4778406
ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:22:43Z

Asg17:

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== Calculations ====

E(NH3)= -56.55776873
2*E(NH3)= -113.11553746
E(N2)= -109.52412868
E(H2)= -1.15928020
3*E(H2)= -3.4778406
ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:22:18Z

Asg17: /* REACTION ENERGIES */

== NH3 ==

=== IMAGE ===
[[File:ASG17_NH3_OPT_POP.txt]]

<jmol><jmolApplet>
<title>Test Molecule - NH3</title>
<color>black</color>
<size>200</size>
<uploadedFileContents>ASG17_NH3_OPT_POP.txt</uploadedFileContents>
</jmolApplet></jmol>

=== OPTIMSATION ===

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of NH3
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy || -56.55776873
|-
| RMS Gradient || 0.00000485
|-
| Point Group || C3V
|-
| N-H Bond Distance || 1.01798
|-
| Bond Angle || 105.741
|-
|}

==== Optimised Parameters ====

The following image shows the final set of parameters fo an optimised molecule of ammonia, NH3.
[[File:NH3_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for NH3.]]

The following image is a graph showing the total energy of each structure throughout the optimsiation process of ammonia, 3. The seventh and final structure has the lowest energy meaning that it is the the optimised structure of NH3 as the structure with the lowest energy is the most stable and so is therefore the optimised structure.

[[File:NH3_Total_Energy_Graph_Optimisation.png|thumb|left|Total Energy of Each Structure in Optimisation Process for NH3.]]

The following image shows the RMS gradient again at each stage of the optimisation process of ammonia, NH3.

[[File:NH3_RMS_Gradient_Norm_Optimisation.png|thumb|left|RMS Gradient of Each Structure in Optimisation Process for NH3.]]

=== VIBRATIONS ===
[[File:NH3_Vibrational_Frequencies.png|thumb|left|Vibrational Frequencies of NH3.]]

==== Vibrational Analysis ====

How many modes do you expect from the 3N-6 rule?

The 3N-6 rule determines the number of normal vibrational modes for a non-linear molecule with an N number of atoms. In the case of ammonia which has 4 atoms, you would expect 6 normal vibrational modes which are shown in the image above.

Which modes are degenerate?

Degerante modes are those that have the same energy, which in the image above is shown by the 'Infrared' column. Vibrational modes 2 and 3 have both the same frequency and infrared energy meaning that they are degenerate. At glance it may appear that they are the same vibrational mode however when viewing the animation, it is clear that they are two separate vibrational modes. Vibrational modes 5 and 6 are also degenerate.

Which modes are "bending" vibrations and which are "bond stretch" vibrations?

Looking at the animations shows that the bending frequencies are vibrational modes 1, 2 and 3 whereas the stretching frequencies are vibrational modes 4, 5 and 6. Without looking at the animations we can also depict which modes are stretching and which are bending by considering the frequencies. Stretching frequencies are much higher than bending frequencies. For the ammonia molecule, the bending frequencies are betewen 1000-1700 whereas the stretching frequencies are between 3400-3600.

Which mode is highly symmetric?

Vibrational modes 1,3,4 and 6 can all be considered as symmetrical modes when the animation is observed however the most symmetrical vibrational mode is no. 4.

One mode is known as the "umbrella" mode, which one is this?

The 'umbrella' mode is vibrational mode no. 1 as when the animation is observed, there is an appearance of an umbrella being opened and closed continuously.

How many bands would you expect to see in an experimental spectrum of gaseous ammonia?

There are 6 vibrational modes overall however as there are 2 sets of degenerate modes, you would expect to see 4 bands in the experimental spectrum.

=== CHARGE ANALYSIS ===

[[File:NH3_Charge_Analysis.png|thumb|left|Charges on Each Atom for NH3.]]
The image on the left shows the charges on each atom for a molecule of ammonia, NH3. It is expected that the nitrogen has a negative charge as it is more electronegative than hydrogen meaning that it will withdraw the bonding pairs of electrons towards itself thus making the charge more negative as electrons are negatively charged and are distributed closer to the nitrogen. The hydrogens are expected to have a positive charge as they are less electronegative meaning that charge is distributed further away from the hydrogens. The same charge is apparent for the three hydrogens as the are the same type of atom with the same electronegativity.

=== REACTION ENERGIES ===

==== H2 ====

{| class="wikitable" border="1"
|+ Summary Table for Optimised Molecule of H2
! Aspect of Molecule !! Value/Answer
|-
| Calculation Method || RB3LYP
|-
| Basis Set || 6-31G(d.p)
|-
| Final Energy ||-1.15928020
|-
| RMS Gradient || 0.09719500
|-
| Point Group || D*H
|-
| Bond Distance || 0.7429
|-
|}

[[File:H2_Final_Set_of_Optimised_Parameters.png|thumb|left|Final Set of Optimised Parameters for H2.]]

==== Calculations ====

E(NH3)= -56.55776873
2*E(NH3)= -113.11553746
E(N2)= -109.52412868
E(H2)= -1.15928020
3*E(H2)= -3.4778406
ΔE=2*E(NH3)-[E(N2)+3*E(H2)]= -0.11356818*2625.5 = -298.17325659

File:H2 Final Set of Optimised Parameters.png

2018-03-02T12:17:27Z

Asg17:

Intro to Molecular Modelling 2 ASG17

2018-03-02T12:17:09Z

Asg17: /* H2 */