Completely Multipolar Model as a General Framework for Many-Body Interactions as Illustrated for Water

Joseph P. Heindel, Selim Sami, Teresa Head-Gordon
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Abstract

We introduce a general framework for many-body force field models, the Completely Multipolar Model (CMM), that utilizes multipolar electrical moments modulated by exponential decay of electron density as a common functional form for all piecewise terms of an energy decomposition analysis of intermolecular interactions. With this common functional form the CMM model establishes well-formulated damped tensors that reach the correct asymptotes at both long- and short-range while formally ensuring no short-range catastrophes. The CMM describes the separable EDA terms of dispersion, exchange polarization, and Pauli repulsion with short-ranged anisotropy, polarization as intramolecular charge fluctuations and induced dipoles, while charge transfer describes explicit movement of charge between molecules, and naturally describes many-body charge transfer by coupling into the polarization equations. We also utilize a new one-body potential that accounts for intramolecular polarization by including an electric field-dependent correction to the Morse potential to ensure that the CMM reproduces all physically relevant monomer properties including the dipole moment, molecular polarizability, and dipole and polarizability derivatives. The quality of the CMM is illustrated through agreement of individual terms of the EDA and excellent extrapolation to energies and geometries of an extensive validation set of water cluster data.
完全多极模型作为多体相互作用的一般框架,以水为例证
我们为多体力场模型引入了一个通用框架,即完全多极模型(CMM),它利用电子密度指数衰减调制的多极电矩作为分子间相互作用能量分解分析中所有分项的通用函数形式。有了这种共同的函数形式,CMM 模型就建立起了完善的阻尼张量,在长程和短程上都能达到正确的渐近线,同时从形式上确保不会出现短程灾难。CMM 描述了具有短程各向异性的分散、交换极化和保利斥力等可分离的 EDA 项,极化为分子内电荷波动和诱导偶极子,而电荷转移则描述了分子间电荷的显式运动,并通过耦合到极化方程中自然地描述了多体电荷转移。我们还利用了一种新的单体电势,通过对莫尔斯电势进行依赖电场的修正来考虑分子内极化,以确保 CMM 重现所有与物理相关的单体特性,包括偶极矩、分子极化率以及偶极和极化率导数。CMM 的质量通过 EDA 单个项的一致性以及对大量水簇数据验证集的能量和几何形状的出色外推法得到了证明。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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