English

MatterSim-MT: A multi-task foundation model for in silico materials characterization

Materials Science 2026-05-11 v1

Abstract

Accurate property characterization is a major bottleneck in materials design. While first-principles methods and task-specific machine-learning models have driven important progress, they remain fundamentally limited in scalability and generalizability across the vast space of structures and properties relevant to real-world materials design. We present MatterSim-MT, a multi-task foundation model for in silico materials simulation and property characterization. The model is pretrained on over 35 million first-principles-labeled structures covering 89 elements, temperatures up to 5000 K and pressures up to 1000 GPa, and is fine-tuned on various properties including Bader charges, magnetic moments, Born effective charges, and dielectric matrices. Out of the box, MatterSim-MT not only serves as a foundation model for predicting material structure, dynamics and thermodynamics, its multi-task architecture also enables a wide range of complex simulations that cannot be captured by potential energy surfaces alone. For example, we demonstrate pressure-dependent LO-TO phonon splitting in SiC with close agreement with experiment, electric hysteresis in ferroelectric BaTiO3, and the cationic-to-anionic redox transition during delithiation of a Li-rich cathode material. Finally, we show that MatterSim-MT scales well with more data and parameters, can be efficiently fine-tuned to higher levels of theory, and can be efficiently extended to new systems via active learning. Overall, we believe this approach provides a scalable route to accurate in silico materials characterization.

Keywords

Cite

@article{arxiv.2605.07927,
  title  = {MatterSim-MT: A multi-task foundation model for in silico materials characterization},
  author = {Han Yang and Xixian Liu and Chenxi Hu and Yichi Zhou and Yu Shi and Chang Liu and Junfu Tan and Jielan Li and Guanzhi Li and Qian Wang and Yu Zhu and Zekun Chen and Shuizhou Chen and Fabian Thiemann and Claudio Zeni and Matthew Horton and Robert Pinsler and Andrew Fowler and Daniel Zügner and Tian Xie and Lixin Sun and Yicheng Chen and Lingyu Kong and Yeqi Bai and Deniz Gunceler and Frank Noé and Hongxia Hao and Ziheng Lu},
  journal= {arXiv preprint arXiv:2605.07927},
  year   = {2026}
}
R2 v1 2026-07-01T12:58:04.801Z