AMOEBA is a molecular mechanics force field that addresses some of the shortcomings of a fixed partial charge model, by including permanent atomic point multipoles through quadrupoles, as well as many-body polarization through the use of point inducible dipoles. In this work, we investigate how well AMOEBA formulates its non-bonded interactions, and how it implicitly incorporates quantum mechanical effects such as charge penetration (CP) and charge transfer (CT), for water–water and water–ion interactions. We find that AMOEBA’s total interaction energies, as a function of distance and over angular scans for the water dimer and for a range of water-monovalent cations, agree well with an advanced density functional theory (DFT) model, whereas...
International audienceClassical molecular dynamics (MD) simulations of electrolyte systems are impor...
We analyze convergence of energies and forces for the AMOEBA classical polarizable model when evalua...
International audienceWe extend the AMOEBA polarizable molecular mechanics force field to the Fe2+ c...
AMOEBA is a molecular mechanics force field that addresses some of the shortcomings of a fixed parti...
In this work, we evaluate the accuracy of the classical AMOEBA model for representing many-body inte...
The importance of incorporating solvent polarization effects into the modeling of solvation processe...
The importance of incorporating solvent polarization effects into the modeling of solvation processe...
Classical potentials based on isotropic and additive atomic charges have been widely used to model m...
Molecular force fields have been approaching a generational transition over the past several years, ...
Molecular force fields have been approaching a generational transition over the past several years, ...
The reliability of molecular mechanics simulations to predict effects of ion binding to proteins dep...
In this work, we have developed an anisotropic polarizable model for the AMOEBA force field that is ...
We present the inclusion of distributed multipoles obtained from the Gaussian Electrostatic Model (G...
We extend the AMOEBA polarizable molecular mechanics force field to the Fe<sup>2+</sup> cation in it...
International audienceClassical molecular dynamics (MD) simulations of electrolyte systems are impor...
We analyze convergence of energies and forces for the AMOEBA classical polarizable model when evalua...
International audienceWe extend the AMOEBA polarizable molecular mechanics force field to the Fe2+ c...
AMOEBA is a molecular mechanics force field that addresses some of the shortcomings of a fixed parti...
In this work, we evaluate the accuracy of the classical AMOEBA model for representing many-body inte...
The importance of incorporating solvent polarization effects into the modeling of solvation processe...
The importance of incorporating solvent polarization effects into the modeling of solvation processe...
Classical potentials based on isotropic and additive atomic charges have been widely used to model m...
Molecular force fields have been approaching a generational transition over the past several years, ...
Molecular force fields have been approaching a generational transition over the past several years, ...
The reliability of molecular mechanics simulations to predict effects of ion binding to proteins dep...
In this work, we have developed an anisotropic polarizable model for the AMOEBA force field that is ...
We present the inclusion of distributed multipoles obtained from the Gaussian Electrostatic Model (G...
We extend the AMOEBA polarizable molecular mechanics force field to the Fe<sup>2+</sup> cation in it...
International audienceClassical molecular dynamics (MD) simulations of electrolyte systems are impor...
We analyze convergence of energies and forces for the AMOEBA classical polarizable model when evalua...
International audienceWe extend the AMOEBA polarizable molecular mechanics force field to the Fe2+ c...