Difference between revisions of "WebMO Electrostatic Potential maps"

From MC Chem Wiki
Jump to navigation Jump to search
 
(11 intermediate revisions by one other user not shown)
Line 39: Line 39:
 
::- Theory: Hartree-Fock
 
::- Theory: Hartree-Fock
 
::- Basic Set: Routine: 6-31(G)d
 
::- Basic Set: Routine: 6-31(G)d
::- Charge: 1
+
::- Charge: 0
 
::- Multiplicity: Singlet
 
::- Multiplicity: Singlet
 
:- Click the blue “continue” arrow to submit the job.
 
:- Click the blue “continue” arrow to submit the job.
Line 48: Line 48:
 
:- Setup the job:
 
:- Setup the job:
 
::- Name: C6H6 (should be this already)
 
::- Name: C6H6 (should be this already)
::- Calculation: Molecular Geometry
+
::- Calculation: Molecular Orbital
 
::- Theory: Hartree-Fock
 
::- Theory: Hartree-Fock
 
::- Basic Set: Routine: 6-31(G)d
 
::- Basic Set: Routine: 6-31(G)d
::- Charge: 1
+
::- Charge: 0
 
::- Multiplicity: Singlet
 
::- Multiplicity: Singlet
 
:- Click the blue “continue” arrow to submit the job.
 
:- Click the blue “continue” arrow to submit the job.
Line 58: Line 58:
 
:- Scroll down to the Molecular Orbitals table and look at the bottom:
 
:- 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]]
 
:[[File:Screen Shot 2020-04-23 at 8.39.16 AM.png|400px]]
...and click the magnifying glass next to the "Potential Energy"
+
...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 the energy values and occupancy as your judge, identify the HOMO and LUMO. View these orbitals by click on the magnifying glass icon. The orbitals can be rotated by clicking and dragging in the viewer window.
+
===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"