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Towards Improved Quantum Machine Learning for Molecular Force Fields

Chemical Physics 2025-12-23 v2 Quantum Physics

Abstract

This study explores the use of equivariant quantum neural networks (QNN) for generating molecular force fields, focusing on the rMD17 dataset. We consider a QNN architecture based on previous research and point out shortcomings in the parametrization of the atomic environments. These shortcomings limit its expressivity as an interatomic potential and precludes transferability between molecules. We propose a revised QNN architecture that addresses these shortcomings. While both QNNs show promise in force prediction, with the revised architecture showing improved accuracy, they struggle with energy prediction. Further, both QNNs architectures fail to demonstrate a meaningful scaling law of decreasing errors with increasing training data. These findings highlight the challenges of scaling QNNs for complex molecular systems and emphasize the need for improved encoding strategies, regularization techniques, and hybrid quantum-classical approaches.

Keywords

Cite

@article{arxiv.2505.03213,
  title  = {Towards Improved Quantum Machine Learning for Molecular Force Fields},
  author = {Yannick Couzinié and Shunsuke Daimon and Hirofumi Nishi and Natsuki Ito and Yusuke Harazono and Yu-ichiro Matsushita},
  journal= {arXiv preprint arXiv:2505.03213},
  year   = {2025}
}

Comments

15 pages, 10 figures, Accepted in Physical Review A

R2 v1 2026-06-28T23:22:29.226Z