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Scalable Machine Learning Force Fields for Macromolecular Systems Through Long-Range Aware Message Passing

Chemical Physics 2026-01-08 v1 Artificial Intelligence Biological Physics

Abstract

Machine learning force fields (MLFFs) have revolutionized molecular simulations by providing quantum mechanical accuracy at the speed of molecular mechanical computations. However, a fundamental reliance of these models on fixed-cutoff architectures limits their applicability to macromolecular systems where long-range interactions dominate. We demonstrate that this locality constraint causes force prediction errors to scale monotonically with system size, revealing a critical architectural bottleneck. To overcome this, we establish the systematically designed MolLR25 ({Mol}ecules with {L}ong-{R}ange effect) benchmark up to 1200 atoms, generated using high-fidelity DFT, and introduce E2Former-LSR, an equivariant transformer that explicitly integrates long-range attention blocks. E2Former-LSR exhibits stable error scaling, achieves superior fidelity in capturing non-covalent decay, and maintains precision on complex protein conformations. Crucially, its efficient design provides up to 30% speedup compared to purely local models. This work validates the necessity of non-local architectures for generalizable MLFFs, enabling high-fidelity molecular dynamics for large-scale chemical and biological systems.

Keywords

Cite

@article{arxiv.2601.03774,
  title  = {Scalable Machine Learning Force Fields for Macromolecular Systems Through Long-Range Aware Message Passing},
  author = {Chu Wang and Lin Huang and Xinran Wei and Tao Qin and Arthur Jiang and Lixue Cheng and Jia Zhang},
  journal= {arXiv preprint arXiv:2601.03774},
  year   = {2026}
}
R2 v1 2026-07-01T08:54:04.648Z