Evaluating the transferability of machine-learned force fields for material property modeling

Machine-learned force fields have generated significant interest in recent years as a tool for molecular dynamics (MD) simulations, with the aim of developing accurate and efficient models that can replace classical interatomic potentials. However, before these models can be confidently applied to m...

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Bibliographic Details
Published in:Computer physics communications 2023-07, Vol.288, p.108723, Article 108723
Main Authors: Mohanty, Shaswat, Yoo, SangHyuk, Kang, Keonwook, Cai, Wei
Format: Article
Language:English
Subjects:
Graph neural network
Machine-learned force field
Optical contrast
Phonon density of states
X-ray photon correlation spectroscopy
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Summary:Machine-learned force fields have generated significant interest in recent years as a tool for molecular dynamics (MD) simulations, with the aim of developing accurate and efficient models that can replace classical interatomic potentials. However, before these models can be confidently applied to materials simulations, they must be thoroughly tested and validated. The existing tests on the radial distribution function and mean-squared displacements are insufficient in assessing the transferability of these models. Here we present a more comprehensive set of benchmarking tests for evaluating the transferability of machine-learned force fields. We use a graph neural network (GNN)-based force field coupled with the OpenMM package to carry out MD simulations for Argon as a test case. Our tests include computational X-ray photon correlation spectroscopy (XPCS) signals, which capture the density fluctuation at various length scales in the liquid phase, as well as phonon density-of-states in the solid phase and the liquid-solid phase transition behavior. Our results show that the model can accurately capture the behavior of the solid phase only when the configurations from the solid phase are included in the training dataset. This underscores the importance of appropriately selecting the training data set when developing machine-learned force fields. The tests presented in this work provide a necessary foundation for the development and application of machine-learned force fields for materials simulations. •Development of a suite of benchmarking tests, including X-ray photon correlation spectroscopy for machine-learned force fields (code available).•Phonon density of states and melting point calculations are necessary tests for the solid phase.•Training data should include both solid and liquid configurations to accurately model material behavior.
ISSN:0010-4655
1879-2944
DOI:10.1016/j.cpc.2023.108723