Classical molecular mechanics force fields typically model interatomic electrostatic interactions with point charges or multipole expansions, which can fail for atoms in close contact due to the lack of a description of penetration effects between their electron clouds. These short-range penetration effects can be significant and are essential for accurate modeling of intermolecular interactions. In this work we report parametrization of an empirical charge–charge function previously reported (Piquemal, J.-P.; J. Phys. Chem. A 2003, 107, 10353) to correct for the missing penetration term in standard molecular mechanics force fields. For this purpose, we have developed a database (S101×7) of 101 unique molecular dimers, each at 7 different ...
Abstract: Accurate and fast evaluation of electrostatic interactions in molecular systems is still o...
We propose a methodology to derive pairwise-additive noncovalent force fields from monomer electron ...
We calculate the polarization portion of electrostatic interactions at the atomic scale using quantu...
International audienceClassical molecular mechanics force fields typically model interatomic electro...
In a typical application of molecular mechanics (MM), the electrostatic interactions are calculated ...
Accurate and fast evaluation of electrostatic interactions in molecular systems is one of the most c...
We develop here a new method to fit the molecular electrostatic potentials obtained in quantum mecha...
A new method to accurately estimate the interaction energy between a large molecule and a smaller li...
ABSTRACT: Accurate and fast evaluation of electrostatic interactions in molecular systems is one of ...
Nearly all standard force fields employ the “sum-of-spheres” approximation, which models intermolecu...
ABSTRACT: We present a simple damping scheme for point-charge electrostatics that could be used dire...
To improve the accuracy and transferability of molecular mechanics force fields, one needs a simple ...
A general, exactly defined and simple method to obtain the parameters for empirical force fields, as...
The effects of charge overlap, or charge penetration, are neglected in most force fields and interac...
Molecular-mechanical (MM) force fields are mathematical functions that map the geometry of a molecul...
Abstract: Accurate and fast evaluation of electrostatic interactions in molecular systems is still o...
We propose a methodology to derive pairwise-additive noncovalent force fields from monomer electron ...
We calculate the polarization portion of electrostatic interactions at the atomic scale using quantu...
International audienceClassical molecular mechanics force fields typically model interatomic electro...
In a typical application of molecular mechanics (MM), the electrostatic interactions are calculated ...
Accurate and fast evaluation of electrostatic interactions in molecular systems is one of the most c...
We develop here a new method to fit the molecular electrostatic potentials obtained in quantum mecha...
A new method to accurately estimate the interaction energy between a large molecule and a smaller li...
ABSTRACT: Accurate and fast evaluation of electrostatic interactions in molecular systems is one of ...
Nearly all standard force fields employ the “sum-of-spheres” approximation, which models intermolecu...
ABSTRACT: We present a simple damping scheme for point-charge electrostatics that could be used dire...
To improve the accuracy and transferability of molecular mechanics force fields, one needs a simple ...
A general, exactly defined and simple method to obtain the parameters for empirical force fields, as...
The effects of charge overlap, or charge penetration, are neglected in most force fields and interac...
Molecular-mechanical (MM) force fields are mathematical functions that map the geometry of a molecul...
Abstract: Accurate and fast evaluation of electrostatic interactions in molecular systems is still o...
We propose a methodology to derive pairwise-additive noncovalent force fields from monomer electron ...
We calculate the polarization portion of electrostatic interactions at the atomic scale using quantu...