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Machine-Learning Interatomic Potentials for Long-Range Systems

Y.-P. Ji, Jiuyang Liang, Zhenli Xu

2025Physical Review Letters13 citationsDOI

Abstract

Machine-learning interatomic potentials have emerged as a revolutionary class of force-field models in molecular simulations, delivering quantum-mechanical accuracy at a fraction of the computational cost and enabling the simulation of large-scale systems over extended timescales. However, they often focus on modeling local environments, neglecting crucial long-range interactions. We propose a sum-of-Gaussians neural network (SOG-Net), a lightweight and versatile framework for integrating long-range interactions into a machine-learning force field. The SOG-Net employs a latent-variable learning network that seamlessly bridges short-range and long-range components, coupled with an efficient Fourier convolution layer that incorporates long-range effects. By learning sum-of-Gaussians multipliers across different convolution layers, the SOG-Net adaptively captures diverse long-range decay behaviors while maintaining close-to-linear computational complexity during training and simulation via nonuniform fast Fourier transforms. The method is demonstrated effective for a broad range of long-range systems.

Topics & Concepts

Convolution (computer science)Computer scienceFocus (optics)Fourier transformStatistical physicsInteratomic potentialClass (philosophy)Range (aeronautics)Computational complexity theoryFast Fourier transformArtificial neural networkMolecular dynamicsComputational modelComplex systemComputational sciencePhysicsAlgorithmComputational physicsFourier analysisPhysical systemDeep learningFraction (chemistry)Biological systemComputational problemCentral forceKernel (algebra)Machine Learning in Materials ScienceTopic ModelingNeural Networks and Applications
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