Direct calculation of the functional inverse of realistic interatomic potentials in field-theoretic simulations.

The Journal of chemical physics Pub Date : 2022-05-23 DOI:10.1063/5.0090333

Alexander Weyman, V. Mavrantzas, H. C. Oettinger

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引用次数: 2

Abstract

We discuss the functional inverse problem in field-theoretic simulations for realistic pairwise potentials such as the Morse potential (widely used in particle simulations as an alternative to the 12-6 Lennard-Jones one), and we propose the following two solutions: (a) a numerical one based on direct inversion on a regular grid or deconvolution and (b) an analytical one by expressing attractive and repulsive contributions to the Morse potential as higher-order derivatives of the Dirac delta function; the resulting system of ordinary differential equations in the saddle-point approximation is solved numerically with appropriate model-consistent boundary conditions using a Newton-Raphson method. For the first time, exponential-like, physically realistic pair interactions are analytically treated and incorporated into a field-theoretic framework. The advantages and disadvantages of the two approaches are discussed in detail in connection with numerical findings from test simulations for the radial distribution function of a monatomic fluid at realistic densities providing direct evidence for the capability of the analytical method to resolve structural features down to the Angstrom scale.

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场论模拟中实际原子间势的泛函逆的直接计算。

本文讨论了实际对偶势如莫尔斯势(广泛用于粒子模拟中作为12-6 Lennard-Jones势的替代方案)的场理论模拟中的泛函逆问题，并提出了以下两种解决方案:(a)基于正则网格直接反演或反褶积的数值模型;(b)通过将摩尔斯势的吸引和排斥贡献表示为狄拉克函数的高阶导数的解析模型;在适当的模型一致边界条件下，采用牛顿-拉夫逊方法对鞍点近似下的常微分方程组进行数值求解。第一次，类指数的，物理上现实的对相互作用被分析处理并纳入场论框架。结合单原子流体在实际密度下径向分布函数的数值模拟结果，详细讨论了这两种方法的优缺点，为解析方法在埃尺度下解析结构特征的能力提供了直接证据。

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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The Journal of chemical physics

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