Nearly all standard force fields employ the “sum-of-spheres” approximation, which models intermolecular interactions purely in terms of interatomic distances. Nonetheless, atoms in molecules can have significantly nonspherical shapes, leading to interatomic interaction energies with strong orientation dependencies. Neglecting this “atomic-level anisotropy” can lead to significant errors in predicting interaction energies. Herein, we propose a simple, transferable, and computationally efficient model (MASTIFF) whereby atomic-level orientation dependence can be incorporated into ab initio intermolecular force fields. MASTIFF includes anisotropic exchange-repulsion, charge penetration, and dispersion effects, in conjunction with a standard tre...
Molecular-mechanical (MM) force fields are mathematical functions that map the geometry of a molecul...
There has been an increased interest to design “smart materials” which can self-assemble into comple...
The theory of intermolecular forces has advanced very greatly in recent years. It has become possibl...
π-interactions are an important motif in chemical and biochemical systems. However, due to their ani...
Computation of intermolecular interactions is a challenge in drug discovery because accurate ab init...
Classical molecular mechanics force fields typically model interatomic electrostatic interactions wi...
International audienceClassical molecular mechanics force fields typically model interatomic electro...
A new method to accurately estimate the interaction energy between a large molecule and a smaller li...
We present a general methodology for generating accurate and transferable ab initio force fields, em...
Abstract: We present an overview of the energy functions used in two Anisotropic Polarizable Molecul...
Specific intermolecular interactions are largely guided by electrostatics. However, the most common ...
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...
We report here the results for an ab initio approach to obtain the parameters needed for molecular s...
Accurate and fast evaluation of electrostatic interactions in molecular systems is one of the most c...
Molecular-mechanical (MM) force fields are mathematical functions that map the geometry of a molecul...
There has been an increased interest to design “smart materials” which can self-assemble into comple...
The theory of intermolecular forces has advanced very greatly in recent years. It has become possibl...
π-interactions are an important motif in chemical and biochemical systems. However, due to their ani...
Computation of intermolecular interactions is a challenge in drug discovery because accurate ab init...
Classical molecular mechanics force fields typically model interatomic electrostatic interactions wi...
International audienceClassical molecular mechanics force fields typically model interatomic electro...
A new method to accurately estimate the interaction energy between a large molecule and a smaller li...
We present a general methodology for generating accurate and transferable ab initio force fields, em...
Abstract: We present an overview of the energy functions used in two Anisotropic Polarizable Molecul...
Specific intermolecular interactions are largely guided by electrostatics. However, the most common ...
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...
We report here the results for an ab initio approach to obtain the parameters needed for molecular s...
Accurate and fast evaluation of electrostatic interactions in molecular systems is one of the most c...
Molecular-mechanical (MM) force fields are mathematical functions that map the geometry of a molecul...
There has been an increased interest to design “smart materials” which can self-assemble into comple...
The theory of intermolecular forces has advanced very greatly in recent years. It has become possibl...