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Machine learning the electric field response of condensed phase systems using perturbed neural network potentials

Author

Listed:
  • Kit Joll

    (University College London)

  • Philipp Schienbein

    (University College London
    Imperial College London)

  • Kevin M. Rosso

    (Pacific Northwest National Laboratory)

  • Jochen Blumberger

    (University College London)

Abstract

The interaction of condensed phase systems with external electric fields is of major importance in a myriad of processes in nature and technology, ranging from the field-directed motion of cells (galvanotaxis), to geochemistry and the formation of ice phases on planets, to field-directed chemical catalysis and energy storage and conversion systems including supercapacitors, batteries and solar cells. Molecular simulation in the presence of electric fields would give important atomistic insight into these processes but applications of the most accurate methods such as ab-initio molecular dynamics (AIMD) are limited in scope by their computational expense. Here we introduce Perturbed Neural Network Potential Molecular Dynamics (PNNP MD) to push back the accessible time and length scales of such simulations. We demonstrate that important dielectric properties of liquid water including the field-induced relaxation dynamics, the dielectric constant and the field-dependent IR spectrum can be machine learned up to surprisingly high field strengths of about 0.2 V Å−1 without loss in accuracy when compared to ab-initio molecular dynamics. This is remarkable because, in contrast to most previous approaches, the two neural networks on which PNNP MD is based are exclusively trained on molecular configurations sampled from zero-field MD simulations, demonstrating that the networks not only interpolate but also reliably extrapolate the field response. PNNP MD is based on rigorous theory yet it is simple, general, modular, and systematically improvable allowing us to obtain atomistic insight into the interaction of a wide range of condensed phase systems with external electric fields.

Suggested Citation

  • Kit Joll & Philipp Schienbein & Kevin M. Rosso & Jochen Blumberger, 2024. "Machine learning the electric field response of condensed phase systems using perturbed neural network potentials," Nature Communications, Nature, vol. 15(1), pages 1-12, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-52491-3
    DOI: 10.1038/s41467-024-52491-3
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    References listed on IDEAS

    as
    1. Ang Gao & Richard C. Remsing, 2022. "Self-consistent determination of long-range electrostatics in neural network potentials," Nature Communications, Nature, vol. 13(1), pages 1-11, December.
    2. Hongxia Hao & Itai Leven & Teresa Head-Gordon, 2022. "Can electric fields drive chemistry for an aqueous microdroplet?," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    3. Oliver T. Unke & Stefan Chmiela & Michael Gastegger & Kristof T. Schütt & Huziel E. Sauceda & Klaus-Robert Müller, 2021. "SpookyNet: Learning force fields with electronic degrees of freedom and nonlocal effects," Nature Communications, Nature, vol. 12(1), pages 1-14, December.
    4. Angelo Montenegro & Chayan Dutta & Muhammet Mammetkuliev & Haotian Shi & Bingya Hou & Dhritiman Bhattacharyya & Bofan Zhao & Stephen B. Cronin & Alexander V. Benderskii, 2021. "Asymmetric response of interfacial water to applied electric fields," Nature, Nature, vol. 594(7861), pages 62-65, June.
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    6. Tsz Wai Ko & Jonas A. Finkler & Stefan Goedecker & Jörg Behler, 2021. "A fourth-generation high-dimensional neural network potential with accurate electrostatics including non-local charge transfer," Nature Communications, Nature, vol. 12(1), pages 1-11, December.
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