Difference between revisions of "WebMO Electrostatic Potential maps"

From MC Chem Wiki
Jump to navigation Jump to search
 
(17 intermediate revisions by one other user not shown)
Line 6: Line 6:
  
 
The figure below shows an example of the electrostatic potential maps for LiH, H<sub>2</sub>, and HF.
 
The figure below shows an example of the electrostatic potential maps for LiH, H<sub>2</sub>, and HF.
::*H<sub>2</sub>, the electrons are evenly distributed among the two H-atoms,
+
::*H<sub>2</sub>, the electrons are evenly distributed among the two H-atoms (green = neutral),
::*LiH, being an ionic compound, the 1s valence electron is transferred to the H-atom showing a clear positive charge (blue - on left) and negative charge (red - on right),
+
::*LiH, being an ionic compound, the 1s valence electron is transferred to the H-atom showing a Li<sup>+</sup>/positive charge (blue - on left) and an H<sup>-</sup>/negative charge (red - on right),
::*HF, being a covalent bond with the highly electronegative F-atom showing showing a clear positive charge (blue - on left) and negative charge (red - on right).
+
::*HF, being a covalent bond with the highly electronegative F-atom showing showing a H<sup>+</sup>/positive charge (blue - on left) and F<sup>-</sup>/negative charge (red - on right).
  
 
[[File:EPmaps.jpg|600px|thumb|center||[https://www.slideserve.com/hermione-mendez/electrostatic-potential-maps-models-that-visually-portray-polarity-and-dipoles reference]]]
 
[[File:EPmaps.jpg|600px|thumb|center||[https://www.slideserve.com/hermione-mendez/electrostatic-potential-maps-models-that-visually-portray-polarity-and-dipoles reference]]]
Line 14: Line 14:
 
'''''Note: these maps are "surface" maps...electrostatic potential surface maps...and represent what the electron distribution looks like from a external perspective.'''''
 
'''''Note: these maps are "surface" maps...electrostatic potential surface maps...and represent what the electron distribution looks like from a external perspective.'''''
  
 +
Using WebMO/Gaussian please complete the following table by optimizing the geometry based the stated level of theory and basis set:
 +
 +
==Activity 1: Generating an Electrostatic Potential Map for Benzene (C<sub>6</sub>H<sub>6</sub>)==
 +
 +
'''Note: this calculation is a 2-step process:
 +
:1) Optimize Geometry, then,
 +
:2) Calculate Molecular Orbitals.
 +
 +
===Step 1: Optimize Geometry for Benzene===
 +
:- Click “New Job”, then “Create New Job”. The Build Molecule window opens,
 +
:- Build C<sub>6</sub>H<sub>6</sub> using the "fragments:
 +
:::... from the menu bar, select Build: Fragments, then
 +
:::- Category: --> Rings
 +
:::- Fragment: --> Benzene
 +
:::- OK
 +
:::...then a single click in the drawing area will generate a benzene ring.
 +
:- Choose Clean-Up > Comprehensive – Mechanics,
 +
:- Symmetrize the molecule...(click "red" D<sub>6h</sub><sup>*</sup> <-- 10th item down in left side menu),
 +
:- Click the blue “continue” arrow in the lower right side of the Build Molecule window.
 +
 +
:- Setup the job as
 +
::- Name: C6H6 (should be this already)
 +
::- Calculation: Geometry Optimization
 +
::- Theory: Hartree-Fock
 +
::- Basic Set: Routine: 6-31(G)d
 +
::- Charge: 0
 +
::- Multiplicity: Singlet
 +
:- Click the blue “continue” arrow to submit the job.
 +
 +
===Step 2: Calculate Molecular Orbitals for Benzene===
 +
:- Once the job is complete, click on the hyperlinked name, C6H6 to open the “View Job” window.
 +
:- Click the "New Job Using This Geometry" button at the bottom of the window, then click the blue “continue” arrow,
 +
:- Setup the job:
 +
::- Name: C6H6 (should be this already)
 +
::- Calculation: Molecular Orbital
 +
::- Theory: Hartree-Fock
 +
::- Basic Set: Routine: 6-31(G)d
 +
::- Charge: 0
 +
::- Multiplicity: Singlet
 +
:- Click the blue “continue” arrow to submit the job.
 +
 +
: - Once the job is complete, click on the "molecular orbital" hyperlinked name to view the “View Job” window.
 +
:- Scroll down to the Molecular Orbitals table and look at the bottom:
 +
:[[File:Screen Shot 2020-04-23 at 8.39.16 AM.png|400px]]
 +
...and click the magnifying glass across from the "Electrostatic Potential" label...this will bring your view back to the top and after a short calculation time, the window will display the electrostatic potential map. Note the positive (blue), negative (red), and neutral (yellow/green) areas.
  
Using WebMO/Gaussian please complete the following table by optimizing the geometry based the stated level of theory and basis set:
+
===Start your...''Report on Electrostatic Potential Map Calculations'' (more below)===
 +
For this lab activity, i am requesting that you prepare a short report...'''''due on Tuesday, April 28th, at 5 pm.'''''
 +
 
 +
When viewing the electrostatic potential (EP) map, you can save this graphic as a PNG file that can be inserted into WORD.
 +
::- When the EP map is displayed, select File: Save Image --> PNG (portable network graphic)...
 +
::- Insert this image into a WORD file and save for later additions.
 +
 
 +
==Activity 2: Generating an Electrostatic Potential Map for substituted Benzenes==
 +
As [http://esr.monmsci.net/wiki/index.php/File:Screen_Shot_2020-04-23_at_8.20.30_AM.png discussed previously], substitutions on the benzene ring can be activating or deactivating towards electrophilic aromatic substitution.
 +
::- Activating groups (electron donating) --> weakly (alkyl, -CH<sub>3</sub>), moderately (alkoxyl, -OCH<sub>3</sub>, hydroxy, -OH), and strongly (-O<sup>-</sup>).
 +
::- Deactivating groups (electron withdrawing)--> weakly (halo, -F, -Cl), moderately (carbonyl, -COR), and strongly (nitro, -NO<sub>2</sub>).
 +
 
 +
Please generate an electrostatic potential map for the following compounds:
 +
::# benzene (done)
 +
::# toluene/methylbenzene
 +
::# anisole/methoxybenzene
 +
::# phenol/hydroxybenzene
 +
::# fluorobenzene
 +
::# benzoic acid/carboxybenzene
 +
::# nitrobenzene
 +
 
 +
Remember: these calculations are a 2-step process:
 +
:1) Optimize Geometry, then,
 +
:2) Calculate Molecular Orbitals.
 +
 
 +
==Report on Electrostatic Potential Map Calculations==
 +
For this lab activity, i am requesting that you prepare a short report...'''''due on Tuesday, April 28th, at 5 pm.''''' (extensions allowed for good reasons)
 +
 
 +
When viewing the electrostatic potential (EP) map, you can save this graphic as a PNG file that can be inserted into WORD.
 +
::- When the EP map is displayed, select File: Save Image --> PNG (portable network graphic)...
 +
::- Insert this image into a WORD file.
 +
 
 +
Report requirements:
 +
:# NAME/CLASS/DATE
 +
:# INTRODUCTION: a short paragraph related to why we are doing these calculations.
 +
:# METHODS: discuss the software used and the details (theory, basis sets,etc) of the calculations. (You do NOT need to do a step by step description of WebMO/Gaussian)
 +
:# RESULTS: present electrostatic potential maps from calculations.
 +
:# DISCUSSION: interpret the results EP maps in terms of the introductory information.
 +
:# CONCLUSION...if needed, not required
 +
:# REFERENCES...if needed, not required

Latest revision as of 17:05, 23 April 2020

(4/23/20, bes)

Exercise 5: Electrostatic Potential Maps

Electrostatic potential maps show the electron distribution (ie. the composite wavefunction for all electrons) within a molecular frame. Did you get that ? <--these pictures are a visual representation of the composite electron wavefunctions.

The figure below shows an example of the electrostatic potential maps for LiH, H2, and HF.

  • H2, the electrons are evenly distributed among the two H-atoms (green = neutral),
  • LiH, being an ionic compound, the 1s valence electron is transferred to the H-atom showing a Li+/positive charge (blue - on left) and an H-/negative charge (red - on right),
  • HF, being a covalent bond with the highly electronegative F-atom showing showing a H+/positive charge (blue - on left) and F-/negative charge (red - on right).
reference

Note: these maps are "surface" maps...electrostatic potential surface maps...and represent what the electron distribution looks like from a external perspective.

Using WebMO/Gaussian please complete the following table by optimizing the geometry based the stated level of theory and basis set:

Activity 1: Generating an Electrostatic Potential Map for Benzene (C6H6)

Note: this calculation is a 2-step process:

1) Optimize Geometry, then,
2) Calculate Molecular Orbitals.

Step 1: Optimize Geometry for Benzene

- Click “New Job”, then “Create New Job”. The Build Molecule window opens,
- Build C6H6 using the "fragments:
... from the menu bar, select Build: Fragments, then
- Category: --> Rings
- Fragment: --> Benzene
- OK
...then a single click in the drawing area will generate a benzene ring.
- Choose Clean-Up > Comprehensive – Mechanics,
- Symmetrize the molecule...(click "red" D6h* <-- 10th item down in left side menu),
- Click the blue “continue” arrow in the lower right side of the Build Molecule window.
- Setup the job as
- Name: C6H6 (should be this already)
- Calculation: Geometry Optimization
- Theory: Hartree-Fock
- Basic Set: Routine: 6-31(G)d
- Charge: 0
- Multiplicity: Singlet
- Click the blue “continue” arrow to submit the job.

Step 2: Calculate Molecular Orbitals for Benzene

- Once the job is complete, click on the hyperlinked name, C6H6 to open the “View Job” window.
- Click the "New Job Using This Geometry" button at the bottom of the window, then click the blue “continue” arrow,
- Setup the job:
- Name: C6H6 (should be this already)
- Calculation: Molecular Orbital
- Theory: Hartree-Fock
- Basic Set: Routine: 6-31(G)d
- Charge: 0
- Multiplicity: Singlet
- Click the blue “continue” arrow to submit the job.
- Once the job is complete, click on the "molecular orbital" hyperlinked name to view the “View Job” window.
- Scroll down to the Molecular Orbitals table and look at the bottom:
Screen Shot 2020-04-23 at 8.39.16 AM.png

...and click the magnifying glass across from the "Electrostatic Potential" label...this will bring your view back to the top and after a short calculation time, the window will display the electrostatic potential map. Note the positive (blue), negative (red), and neutral (yellow/green) areas.

Start your...Report on Electrostatic Potential Map Calculations (more below)

For this lab activity, i am requesting that you prepare a short report...due on Tuesday, April 28th, at 5 pm.

When viewing the electrostatic potential (EP) map, you can save this graphic as a PNG file that can be inserted into WORD.

- When the EP map is displayed, select File: Save Image --> PNG (portable network graphic)...
- Insert this image into a WORD file and save for later additions.

Activity 2: Generating an Electrostatic Potential Map for substituted Benzenes

As discussed previously, substitutions on the benzene ring can be activating or deactivating towards electrophilic aromatic substitution.

- Activating groups (electron donating) --> weakly (alkyl, -CH3), moderately (alkoxyl, -OCH3, hydroxy, -OH), and strongly (-O-).
- Deactivating groups (electron withdrawing)--> weakly (halo, -F, -Cl), moderately (carbonyl, -COR), and strongly (nitro, -NO2).

Please generate an electrostatic potential map for the following compounds:

  1. benzene (done)
  2. toluene/methylbenzene
  3. anisole/methoxybenzene
  4. phenol/hydroxybenzene
  5. fluorobenzene
  6. benzoic acid/carboxybenzene
  7. nitrobenzene

Remember: these calculations are a 2-step process:

1) Optimize Geometry, then,
2) Calculate Molecular Orbitals.

Report on Electrostatic Potential Map Calculations

For this lab activity, i am requesting that you prepare a short report...due on Tuesday, April 28th, at 5 pm. (extensions allowed for good reasons)

When viewing the electrostatic potential (EP) map, you can save this graphic as a PNG file that can be inserted into WORD.

- When the EP map is displayed, select File: Save Image --> PNG (portable network graphic)...
- Insert this image into a WORD file.

Report requirements:

  1. NAME/CLASS/DATE
  2. INTRODUCTION: a short paragraph related to why we are doing these calculations.
  3. METHODS: discuss the software used and the details (theory, basis sets,etc) of the calculations. (You do NOT need to do a step by step description of WebMO/Gaussian)
  4. RESULTS: present electrostatic potential maps from calculations.
  5. DISCUSSION: interpret the results EP maps in terms of the introductory information.
  6. CONCLUSION...if needed, not required
  7. REFERENCES...if needed, not required
Retrieved from "http://205.166.159.208/wiki/index.php?title=WebMO_Electrostatic_Potential_maps&oldid=13853"