Including the Effect of Solvent on Quantum Mechanical Calculations: The Continuum Model Approach
SOLVENT MODELS Classical Ensemble Treatments Mixed QM/MM Quantum Mechanical Reaction Fields
SOLVENT MODELS Classical Ensemble Treatments Mixed QM/MM Quantum Mechanical Reaction Fields truncated electrostatics complete electrostatics
SOLVENT MODELS Classical Ensemble Treatments Mixed QM/MM Quantum Mechanical Reaction Fields truncated electrostatics Onsager Sphere Method complete electrostatics
SOLVENT MODELS Classical Ensemble Treatments Mixed QM/MM Quantum Mechanical Reaction Fields truncated electrostatics Onsager Sphere Method Ellipsoidal Methods complete electrostatics
SOLVENT MODELS Classical Ensemble Treatments Mixed QM/MM Quantum Mechanical Reaction Fields truncated electrostatics Onsager Sphere Method Ellipsoidal Methods SAM1 complete electrostatics
SOLVENT MODELS Classical Ensemble Treatments Mixed QM/MM Quantum Mechanical Reaction Fields truncated electrostatics Onsager Sphere Method Ellipsoidal Methods SAM1 complete electrostatics polarizable continuum model (PCM)
SOLVENT MODELS Classical Ensemble Treatments Mixed QM/MM Quantum Mechanical Reaction Fields truncated electrostatics Onsager Sphere Method Ellipsoidal Methods SAM1 complete electrostatics polarizable continuum model (PCM) isodensity PCM
SOLVENT MODELS Classical Ensemble Treatments Mixed QM/MM Quantum Mechanical Reaction Fields truncated electrostatics Onsager Sphere Method Ellipsoidal Methods SAM1 complete electrostatics polarizable continuum model (PCM) isodensity PCM conductor-like PCM
Onsager Self-Consistent Reaction Field (SCRF) Volume of sphere chosen based on molecular volume
Implementation of Onsager SCRF Method Wong - Wiberg - Frisch Analytical First and Second Derivatives Molecular Geometries Vibrational Frequencies Fast, but Limited Molecules that are not spheres? Other solvent-solute interaction?
Furfuraldehyde conformational equilibrium Which isomer is more stable? How much more stable?
Furfuraldehyde conformational equilibrium Which isomer is more stable? How much more stable? Syn - Anti [kcal/mol] Onsager* Expt. Gas phase dimethyl ether (-120) *Theoretical model is RHF/6-31+G(d)//RHF/6-31G(d) gas phase geometry
Furfuraldehyde conformational equilibrium Which isomer is more stable? How much more stable? Syn - Anti [kcal/mol] Onsager* Expt. Gas phase dimethyl ether (-120) *Theoretical model is B3LYP/6-31+G(d)//RHF/6-31G(d) gas phase geometry
Dipole formula can be generalized for higher-order electrostatic terms:
Furfuraldehyde conformational equilibrium Syn - Anti [kcal/mol] Spherical Cavity Dipole Quadrupole Octapole Hexadecapole Expt Solvent is dimethylether
Rivail and Rinaldi (QCPE 1992) Extended to ellipsoidal cavity shape used VDW radii to determine sixth-order electrostatics first derivatives
Rivail and Rinaldi (QCPE 1992) Extended to ellipsoidal cavity shape used VDW radii to determine sixth-order electrostatics first derivatives 2-nitrovinylamine rotational barrier: E FormZ form
Rivail and Rinaldi (QCPE 1992) E FormZ form TS
Rivail and Rinaldi (QCPE 1992) 2-nitrovinylamine rotational barrier: Solvent is N,N-dimethylformamide
What if our molecule is not in the shape of a basketball or football?
Isodensity Polarizable Continuum Model Keith - Foresman - Wiberg - Frisch (JPC 1996) Cavity surface defined as an isodensity of the solute is used because it gives expt molecular volumes Solute is polarized by the solvent represented by point charges on cavity surface Self-Consistent Solution is found: cavity changes each macroiteration
Furfuraldehyde conformational equilibrium Model is B3LYP/6-31+G(d)//HF/6-31G(d) gas
Acetone hydration energy
Really two problems here: 1. Experiment is Free Energy, calculation includes only solute-solvent electrostatic interaction. 2. Hydrogen Bonding
Pisa Polarizable Continuum Model (PCM) Miertus - Tomasi - Mennucci - Cammi (1980-present) Cavity based on overlapping spheres centered on atoms Free Energy Terms built in as solvent parameters cavitation energy dispersion energy repulsion energy Specialized Surface Charge Schemes patches for interface regions
Conductor Polarizable Continuum Model (CPCM) Barone - Cossi ( JPCA 1998) Extension of Pisa Model More Appropriate for Polar Liquids electrostatic potential goes to zero on the surface Specialized Surface Charge Schemes patches for interface regions
Conductor Polarizable Continuum Model (CPCM) Barone - Cossi ( JPCA 1998) Free Energies of Hydration: CPCM Model; basis set is 6-31G(d); TSNum=60; gas phase geometries; Barone & Cossi, JPCA 1998.
Conductor Polarizable Continuum Model (CPCM) Barone - Cossi ( JPCA 1998) Free Energies of Hydration: CPCM Model; basis set is 6-31G(d); TSNum=60; gas phase geometries; Barone & Cossi, JPCA Problem: Cavity tied to Method Not Obvious How to determine radii of spheres
Isodensity Methods better for determining cavity without parameterization Pisa model parameters useful when non-electrostatic terms are important SUMMARY In Progress: Merging the two methods
Other Applications
Menschutkin Reaction:
Is this reaction endothermic or exothermic?
Menschutkin Reaction: Is this reaction endothermic or exothermic? What is the activation energy and mechanism?
Menschutkin Reaction: Is this reaction endothermic or exothermic? What is the activation energy and mechanism? How does solvent influence this?
Menschutkin Reaction:
Solvent Effects on Electronic Spectra
Absorption Spectrum of Acetone
DUAL FLUORESCENCE
4-aminobenzonitrile 4ABN 4-dimethylaminobenzonitrile 4DMABN
Twisted Intermolecular Charge Transfer TICT
Thanks AEleen Frisch Ken Wiberg, Yale University Mike Frisch, Gaussian Inc. Todd Keith, SemiChem Hans Peter Luthi, ETH Zurich Brian Williams, Bucknell Univeristy