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# Computation of covalent state of allyl radical
 
# Computation of covalent state of allyl radical
## Compute the VBSCF wave function for the covalent state of the allyl radical (6-31G basis set) using the covalent structures you have chosen (paper Ex. 1.2). What are the weights of the different VB structures. Was that expected?<br/>  
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## Compute the VBSCF wave function for the covalent state of the allyl radical (6-31G* basis set) using the covalent structures you have chosen (paper Ex. 1.2). What are the weights of the different VB structures. Was that expected?<br/>  
 
## What is the wavefunction in determinant description? What is the spin population? Do the calculated results agree with your answer for paper Ex. 2.1?  
 
## What is the wavefunction in determinant description? What is the spin population? Do the calculated results agree with your answer for paper Ex. 2.1?  
## Repeat the calcultions for the first excited state using '' "nstate=1" ''. What is the the wavefunction? Use determinant description. What is the spin population in this case? Was that what you expected?   
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## Repeat the calculation for the first excited state using '' "nstate=1" ''. What is the the wavefunction? Use determinant description. What is the spin population in this case? Was that expected?   
 
# Computation of allyl radical energy and weights:
 
# Computation of allyl radical energy and weights:
## Compute a VBSCF wave function for allyl radical (6-31G basis set) using your selected set of structures (questions 1.2 and 3.1). Compute a VBSCF wave function including the complete set of VB structures (the adiabatic wavefunction), using the '' "str=full" '' keyword. Compare the weights and energies for both wave functions to validate your selection of structures.
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## Compute a VBSCF wave function for allyl radical (6-31G* basis set) using your selected set of structures (questions 1.2 and 3.1). Compute a VBSCF wave function including the complete set of VB structures (the adiabatic wavefunction), using the '' "str=full" '' keyword. Compare the weights and energies for both wave functions to validate your selection of structures.
## Compute for allyl radical a BOVB wave function  which includes only your selected set of most chemically meaningful structures (use the guess orbitals obtained at the VBSCF level by copying the vbscf_filename.orb file after VBSCF calculation to bovb_filename.gus file in addition remember that only the ISCF=2 option can be used for BOVB). Compare the weights obtained at the VBSCF and BOVB level.  
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## Compute for allyl radical a BOVB wave function  which includes only your selected set of most chemically meaningful structures (remember to use the guess orbitals obtained at the VBSCF level). Compare the weights obtained at the VBSCF and BOVB levels.  
 
# Computation of resonance energies :
 
# Computation of resonance energies :
 
## We want to build a wave-function corresponding to only one ''Lewis'' (diabatic) structure for the allyl radical. To do so, we will include in the wave-function only one covalent structure, and the ionic structures associated with this covalent bond. Propose a selection of ''VB'' structures which would describe one ''Lewis'' structure for the allyl radical.
 
## We want to build a wave-function corresponding to only one ''Lewis'' (diabatic) structure for the allyl radical. To do so, we will include in the wave-function only one covalent structure, and the ionic structures associated with this covalent bond. Propose a selection of ''VB'' structures which would describe one ''Lewis'' structure for the allyl radical.

Version du 12 juillet 2012 à 09:24

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VB applications on PI systems

In all the following exercises, <math>\pi</math> the system will be taken as active, and the <math>\sigma</math> system as inactive. In all VB calculations, the <math>\sigma</math> orbitals shall be described by MOs delocalized onto the whole molecule.




>> general guidelines for BOVB calculations