English

Transfer learning for chemically accurate interatomic neural network potentials

Computational Physics 2023-03-22 v2 Machine Learning

Abstract

Developing machine learning-based interatomic potentials from ab-initio electronic structure methods remains a challenging task for computational chemistry and materials science. This work studies the capability of transfer learning, in particular discriminative fine-tuning, for efficiently generating chemically accurate interatomic neural network potentials on organic molecules from the MD17 and ANI data sets. We show that pre-training the network parameters on data obtained from density functional calculations considerably improves the sample efficiency of models trained on more accurate ab-initio data. Additionally, we show that fine-tuning with energy labels alone can suffice to obtain accurate atomic forces and run large-scale atomistic simulations, provided a well-designed fine-tuning data set. We also investigate possible limitations of transfer learning, especially regarding the design and size of the pre-training and fine-tuning data sets. Finally, we provide GM-NN potentials pre-trained and fine-tuned on the ANI-1x and ANI-1ccx data sets, which can easily be fine-tuned on and applied to organic molecules.

Keywords

Cite

@article{arxiv.2212.03916,
  title  = {Transfer learning for chemically accurate interatomic neural network potentials},
  author = {Viktor Zaverkin and David Holzmüller and Luca Bonfirraro and Johannes Kästner},
  journal= {arXiv preprint arXiv:2212.03916},
  year   = {2023}
}
R2 v1 2026-06-28T07:25:12.869Z