We propose a methodology to derive pairwise-additive noncovalent force fields from monomer electron densities without any empirical input. Energy expressions are based on the symmetry-adapted perturbation theory (SAPT) decomposition of interaction energies. This ensures a physically motivated force field featuring an electrostatic, exchange repulsion, dispersion, and induction contribution, which contains two types of parameters. First, each contribution depends on several fixed atomic parameters, resulting from a partitioning of the monomer electron density. Second, each of the last three contributions (exchange-repulsion, dispersion, and induction) contains exactly one linear fitting parameter. These three so-called interaction parameters...
Author Institution: Department of Chemistry and Biochemistry, The Ohio State University, Columbus, O...
We present a general methodology for generating accurate and transferable ab initio force fields, em...
Computer simulation increasingly complements experimental efforts to describe nanoscale structure fo...
We propose a methodology to derive pairwise-additive noncovalent force fields from monomer electron ...
We propose a methodology to derive pairwise-additive noncovalent force fields from monomer electron ...
Atomic partial charges appear in the Coulomb term of many force-field models and can be derived from...
ABSTRACT: Quantum mechanical (QM) calculations of noncovalent interactions are uniquely useful as to...
Computation of intermolecular interactions is a challenge in drug discovery because accurate ab init...
This thesis pioneers the development of non-empirical anisotropic atom-atom force-fields for organic...
Quantum mechanical (QM) calculations of noncovalent interactions are uniquely useful as tools to tes...
A procedure is given by which parameters of nonbonded interactions in a molecular mechanics energy f...
The accuracy of molecular mechanics force fields (FF) reveals critical for applications where precis...
The quality of atomistic simulations depends decisively on the accuracy of the underlying energy fun...
A rapid method to parameterize the intramolecular component of classical force fields for complex co...
Accurate and fast evaluation of electrostatic interactions in molecular systems is one of the most c...
Author Institution: Department of Chemistry and Biochemistry, The Ohio State University, Columbus, O...
We present a general methodology for generating accurate and transferable ab initio force fields, em...
Computer simulation increasingly complements experimental efforts to describe nanoscale structure fo...
We propose a methodology to derive pairwise-additive noncovalent force fields from monomer electron ...
We propose a methodology to derive pairwise-additive noncovalent force fields from monomer electron ...
Atomic partial charges appear in the Coulomb term of many force-field models and can be derived from...
ABSTRACT: Quantum mechanical (QM) calculations of noncovalent interactions are uniquely useful as to...
Computation of intermolecular interactions is a challenge in drug discovery because accurate ab init...
This thesis pioneers the development of non-empirical anisotropic atom-atom force-fields for organic...
Quantum mechanical (QM) calculations of noncovalent interactions are uniquely useful as tools to tes...
A procedure is given by which parameters of nonbonded interactions in a molecular mechanics energy f...
The accuracy of molecular mechanics force fields (FF) reveals critical for applications where precis...
The quality of atomistic simulations depends decisively on the accuracy of the underlying energy fun...
A rapid method to parameterize the intramolecular component of classical force fields for complex co...
Accurate and fast evaluation of electrostatic interactions in molecular systems is one of the most c...
Author Institution: Department of Chemistry and Biochemistry, The Ohio State University, Columbus, O...
We present a general methodology for generating accurate and transferable ab initio force fields, em...
Computer simulation increasingly complements experimental efforts to describe nanoscale structure fo...