Issue 44, 2023

Hybrid classical/machine-learning force fields for the accurate description of molecular condensed-phase systems

Abstract

Electronic structure methods offer in principle accurate predictions of molecular properties, however, their applicability is limited by computational costs. Empirical methods are cheaper, but come with inherent approximations and are dependent on the quality and quantity of training data. The rise of machine learning (ML) force fields (FFs) exacerbates limitations related to training data even further, especially for condensed-phase systems for which the generation of large and high-quality training datasets is difficult. Here, we propose a hybrid ML/classical FF model that is parametrized exclusively on high-quality ab initio data of dimers and monomers in vacuum but is transferable to condensed-phase systems. The proposed hybrid model combines our previous ML-parametrized classical model with ML corrections for situations where classical approximations break down, thus combining the robustness and efficiency of classical FFs with the flexibility of ML. Extensive validation on benchmarking datasets and experimental condensed-phase data, including organic liquids and small-molecule crystal structures, showcases how the proposed approach may promote FF development and unlock the full potential of classical FFs.

Graphical abstract: Hybrid classical/machine-learning force fields for the accurate description of molecular condensed-phase systems

Supplementary files

Article information

Article type
Edge Article
Submitted
17 Aug 2023
Accepted
24 Oct 2023
First published
31 Oct 2023
This article is Open Access

All publication charges for this article have been paid for by the Royal Society of Chemistry
Creative Commons BY-NC license

Chem. Sci., 2023,14, 12661-12675

Hybrid classical/machine-learning force fields for the accurate description of molecular condensed-phase systems

M. Thürlemann and S. Riniker, Chem. Sci., 2023, 14, 12661 DOI: 10.1039/D3SC04317G

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