English

SimPoly: Simulation of Polymers with Machine Learning Force Fields Derived from First Principles

Chemical Physics 2025-10-16 v1

Abstract

Polymers are a versatile class of materials with widespread industrial applications. Advanced computational tools could revolutionize their design, but their complex, multi-scale nature poses significant modeling challenges. Conventional force fields often lack the accuracy and transferability required to capture the intricate interactions governing polymer behavior. Conversely, quantum-chemical methods are computationally prohibitive for the large systems and long timescales required to simulate relevant polymer phenomena. Here, we overcome these limitations with a machine learning force field (MLFF) approach. We demonstrate that macroscopic properties for a broad range of polymers can be predicted ab initio, without fitting to experimental data. Specifically, we develop a fast and scalable MLFF to accurately predict polymer densities, outperforming established classical force fields. Our MLFF also captures second-order phase transitions, enabling the prediction of glass transition temperatures. To accelerate progress in this domain, we introduce a benchmark of experimental bulk properties for 130 polymers and an accompanying quantum-chemical dataset. This work lays the foundation for a fully in silico design pipeline for next-generation polymeric materials.

Keywords

Cite

@article{arxiv.2510.13696,
  title  = {SimPoly: Simulation of Polymers with Machine Learning Force Fields Derived from First Principles},
  author = {Gregor N. C. Simm and Jean Hélie and Hannes Schulz and Yicheng Chen and Guillem Simeon and Anna Kuzina and Ernesto Martinez-Baez and Piero Gasparotto and Gabriele Tocci and Chi Chen and Yatao Li and Lixue Cheng and Zun Wang and Bichlien H. Nguyen and Jake A. Smith and Lixin Sun},
  journal= {arXiv preprint arXiv:2510.13696},
  year   = {2025}
}
R2 v1 2026-07-01T06:39:14.889Z