Stress tensor and constant pressure simulation for polarizable Gaussian multipole model

Our previous article has established the theory of molecular dynamics (MD) simulations for systems modeled with the polarizable Gaussian multipole (pGM) electrostatics [Wei et al., J. Chem. Phys. 153(11), 114116 (2020)]. Specifically, we proposed the covalent basis vector framework to define the permanent multipoles and derived closed-form energy and force expressions to facilitate an efficient implementation of pGM electrostatics. In this study, we move forward to derive the pGM internal stress tensor for constant pressure MD simulations with the pGM electrostatics. Three different formulations are presented for the flexible, rigid, and short-range screened systems, respectively. The analytical formulations were implemented in the SANDER program in the Amber package and were first validated with the finite-difference method for two different boxes of pGM water molecules. This is followed by a constant temperature and constant pressure MD simulation for a box of 512 pGM water molecules. Our results show that the simulation system stabilized at a physically reasonable state and maintained the balance with the externally applied pressure. In addition, several fundamental differences were observed between the pGM and classic point charge models in terms of the simulation behaviors, indicating more extensive parameterization is necessary to utilize the pGM electrostatics.& nbsp;Published by AIP Publishing.

Automated summary

In this article, we establish the theory of molecular dynamics (MD) simulations with the polarizable Gaussian multipole (pGM) electrostatics, and derive the pGM internal stress tensor for constant pressure MD simulations. We present different formulations for flexible, rigid, and short-range screened systems. The analytical formulations are implemented and validated, and differences between pGM and classic point charge models are observed.