Accelerating Two-Dimensional Materials Research via a Universal Interatomic Potential and Large Language Model Agent

Abstract: Accurate interatomic potentials (IAPs) are essential for modeling the potential energy surfaces (PES) that govern atomic interactions in materials. However, most existing IAPs are developed for bulk materials and struggle to accurately and efficiently capture the diverse chemical environment of two-dimensional (2D) materials. This limitation poses a significant barrier to the large-scale design and simulation of emerging 2D systems. To address this challenge, we present a universal interatomic potential tailored for 2D materials. Our model is trained on a dataset comprising 327,062 structure-energy-force-stress mappings derived from 20,114 2D materials, spanning 89 chemical elements. The results show high predictive accuracy, with mean absolute errors of 6 meV/atom for energies, 80 meV/\AA for atomic forces, and 0.067 GPa for stress tensors. It demonstrates broad applicability across a range of atomistic tasks, including structural relaxation, lattice dynamics, molecular dynamics, material discovery, and so on. To further enhance usability and accessibility, we introduce an intelligent agent powered by a LLM, enabling natural language interaction for 2D materials property simulations. Our work provides not only a precise and universal IAP for 2D systems, but also an intelligent, user-friendly platform that enables high-throughput screening, property prediction, and theoretical exploration, thereby accelerating advances in 2D materials research.