Extraction of Material Properties through Multi-fidelity Deep Learning from Molecular Dynamics Simulation

TL;DR

This paper introduces a multi-fidelity physics-informed neural network approach to efficiently simulate long-range molecular dynamics, significantly reducing computational costs while maintaining high accuracy in predicting material properties.

Contribution

It presents the first implementation of MPINN with MD simulations, enabling accurate nanoscale property predictions with fewer high-fidelity simulations and reduced computational expense.

Findings

Achieved 68% reduction in computational costs.

Accurately predicted system energy, pressure, and diffusion coefficients.

Validated MPINN on argon-copper nanofluid viscosity across various conditions.

Abstract

Simulation of reasonable timescales for any long physical process using molecular dynamics (MD) is a major challenge in computational physics. In this study, we have implemented an approach based on multi-fidelity physics informed neural network (MPINN) to achieve long-range MD simulation results over a large sample space with significantly less computational cost. The fidelity of our present multi-fidelity study is based on the integration timestep size of MD simulations. While MD simulations with larger timestep produce results with lower level of accuracy, it can provide enough computationally cheap training data for MPINN to learn an accurate relationship between these low-fidelity results and high-fidelity MD results obtained using smaller simulation timestep. We have performed two benchmark studies, involving one and two component LJ systems, to determine the optimum percentage of high-fidelity training data required to achieve accurate results with high computational saving. The results show that important system properties such as system energy per atom, system pressure and diffusion coefficients can be determined with high accuracy while saving 68% computational costs. Finally, as a demonstration of the applicability of our present methodology in practical MD studies, we have studied the viscosity of argon-copper nanofluid and its variation with temperature and volume fraction by MD simulation using MPINN. Then we have compared them with numerous previous studies and theoretical models. Our results indicate that MPINN can predict accurate nanofluid viscosity at a wide range of sample space with significantly small number of MD simulations. Our present methodology is the first implementation of MPINN in conjunction with MD simulation for predicting nanoscale properties. This can pave pathways to investigate more complex engineering problems that demand long-range MD simulations.