Issue 7, 2023

Transfer learning for chemically accurate interatomic neural network potentials

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.

Graphical abstract: Transfer learning for chemically accurate interatomic neural network potentials

Supplementary files

Article information

Article type
Paper
Submitted
12 Dec. 2022
Accepted
30 Janv. 2023
First published
31 Janv. 2023

Phys. Chem. Chem. Phys., 2023,25, 5383-5396

Transfer learning for chemically accurate interatomic neural network potentials

V. Zaverkin, D. Holzmüller, L. Bonfirraro and J. Kästner, Phys. Chem. Chem. Phys., 2023, 25, 5383 DOI: 10.1039/D2CP05793J

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