Transferable Neural Wavefunctions for Solids

Michael Scherbela; Leon Gerard; Halvard Sutterud; Matthew Foulkes; Philipp Grohs

doi:10.1038/s43588-025-00872-z

Transferable Neural Wavefunctions for Solids

Michael Scherbela
, Leon Gerard
, Halvard Sutterud
, Matthew Foulkes
, Philipp Grohs

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Deep-learning-based variational Monte Carlo has emerged as a highly accurate method for solving the many-electron Schrödinger equation. Despite favorable scaling with the number of electrons, O(nel4), the practical value of deep-learning-based variational Monte Carlo is limited by the high cost of optimizing the neural network weights for every system studied. Recent research has proposed optimizing a single neural network across multiple systems, reducing the cost per system. Here we extend this approach to solids, which require numerous calculations across different geometries, boundary conditions and supercell sizes. We demonstrate that optimization of a single ansatz across these variations significantly reduces optimization steps. Furthermore, we successfully transfer a network trained on 2 × 2 × 2 supercells of LiH, to 3 × 3 × 3 supercells, reducing the number of optimization steps required to simulate the large system by a factor of 50 compared with previous work.

Original language	English
Pages (from-to)	1147–1157
Number of pages	11
Journal	Nature Computational Science
Volume	5
Issue number	12
DOIs	https://doi.org/10.1038/s43588-025-00872-z
Publication status	Published - Dec 2025

Austrian Fields of Science 2012

101014 Numerical mathematics
104027 Computational chemistry
102018 Artificial neural networks

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Cite this

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title = "Transferable Neural Wavefunctions for Solids",

abstract = "Deep-learning-based variational Monte Carlo has emerged as a highly accurate method for solving the many-electron Schr{\"o}dinger equation. Despite favorable scaling with the number of electrons, O(nel4), the practical value of deep-learning-based variational Monte Carlo is limited by the high cost of optimizing the neural network weights for every system studied. Recent research has proposed optimizing a single neural network across multiple systems, reducing the cost per system. Here we extend this approach to solids, which require numerous calculations across different geometries, boundary conditions and supercell sizes. We demonstrate that optimization of a single ansatz across these variations significantly reduces optimization steps. Furthermore, we successfully transfer a network trained on 2 × 2 × 2 supercells of LiH, to 3 × 3 × 3 supercells, reducing the number of optimization steps required to simulate the large system by a factor of 50 compared with previous work.",

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AU - Scherbela, Michael

AU - Gerard, Leon

AU - Sutterud, Halvard

AU - Foulkes, Matthew

AU - Grohs, Philipp

PY - 2025/12

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AB - Deep-learning-based variational Monte Carlo has emerged as a highly accurate method for solving the many-electron Schrödinger equation. Despite favorable scaling with the number of electrons, O(nel4), the practical value of deep-learning-based variational Monte Carlo is limited by the high cost of optimizing the neural network weights for every system studied. Recent research has proposed optimizing a single neural network across multiple systems, reducing the cost per system. Here we extend this approach to solids, which require numerous calculations across different geometries, boundary conditions and supercell sizes. We demonstrate that optimization of a single ansatz across these variations significantly reduces optimization steps. Furthermore, we successfully transfer a network trained on 2 × 2 × 2 supercells of LiH, to 3 × 3 × 3 supercells, reducing the number of optimization steps required to simulate the large system by a factor of 50 compared with previous work.

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Transferable Neural Wavefunctions for Solids

Abstract

Austrian Fields of Science 2012

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