A foundation model for atomistic materials chemistry

Ilyes Batatia; Philipp Benner; Yuan Chiang; Alin M. Elena; D\'avid P. Kov\'acs; Janosh Riebesell; Xavier R. Advincula; Mark Asta; Matthew Avaylon; William J. Baldwin; Fabian Berger; Noam Bernstein; Arghya Bhowmik; Filippo Bigi; Samuel M. Blau; Vlad C\u{a}rare; Michele Ceriotti; Sanggyu Chong; James P. Darby; Sandip De; Flaviano Della Pia; Volker L. Deringer; Rokas Elijo\v{s}ius; Zakariya El-Machachi; Fabio Falcioni; Edvin Fako; Andrea C. Ferrari; John L. A. Gardner; Mikolaj J. Gawkowski; Annalena Genreith-Schriever; Janine George; Rhys E. A. Goodall; Jonas Grandel; Clare P. Grey; Petr Grigorev; Shuang Han; Will Handley; Hendrik H. Heenen; Kersti Hermansson; Christian Holm; Cheuk Hin Ho; Stephan Hofmann; Jad Jaafar; Konstantin S. Jakob; Hyunwook Jung; Venkat Kapil; Aaron D. Kaplan; Nima Karimitari; James R. Kermode; Panagiotis Kourtis; Namu Kroupa; Jolla Kullgren; Matthew C. Kuner; Domantas Kuryla; Guoda Liepuoniute; Chen Lin; Johannes T. Margraf; Ioan-Bogdan Magd\u{a}u; Angelos Michaelides; J. Harry Moore; Aakash A. Naik; Samuel P. Niblett; Sam Walton Norwood; Niamh O'Neill; Christoph Ortner; Kristin A. Persson; Karsten Reuter; Andrew S. Rosen; Louise A. M. Rosset; Lars L. Schaaf; Christoph Schran; Benjamin X. Shi; Eric Sivonxay; Tam\'as K. Stenczel; Viktor Svahn; Christopher Sutton; Thomas D. Swinburne; Jules Tilly; Cas van der Oord; Santiago Vargas; Eszter Varga-Umbrich; Tejs Vegge; Martin Vondr\'ak; Yangshuai Wang; William C. Witt; Thomas Wolf; Fabian Zills; and G\'abor Cs\'anyi

arXiv:2401.00096·physics.chem-ph·September 8, 2025·238 cites

A foundation model for atomistic materials chemistry

Ilyes Batatia, Philipp Benner, Yuan Chiang, Alin M. Elena, D\'avid P. Kov\'acs, Janosh Riebesell, Xavier R. Advincula, Mark Asta, Matthew Avaylon, William J. Baldwin, Fabian Berger, Noam Bernstein, Arghya Bhowmik, Filippo Bigi, Samuel M. Blau, Vlad C\u{a}rare, Michele Ceriotti

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Open Access 5 Repos 1 Models

TL;DR

This paper introduces MACE-MP-0, a versatile foundation machine learning model capable of accurately simulating a wide range of atomistic materials and molecules, significantly reducing development effort and enhancing transferability.

Contribution

The authors develop a general-purpose, stable ML force field trained on a public dataset that can be fine-tuned for specific applications, advancing atomistic modeling.

Findings

01

Model demonstrates qualitative and quantitative accuracy across diverse physical systems.

02

Enables stable molecular dynamics simulations for solids, liquids, gases, and biomolecules.

03

Reduces time and effort needed for system-specific potential development.

Abstract

Atomistic simulations of matter, especially those that leverage first-principles (ab initio) electronic structure theory, provide a microscopic view of the world, underpinning much of our understanding of chemistry and materials science. Over the last decade or so, machine-learned force fields have transformed atomistic modeling by enabling simulations of ab initio quality over unprecedented time and length scales. However, early ML force fields have largely been limited by: (i) the substantial computational and human effort of developing and validating potentials for each particular system of interest; and (ii) a general lack of transferability from one chemical system to the next. Here we show that it is possible to create a general-purpose atomistic ML model, trained on a public dataset of moderate size, that is capable of running stable molecular dynamics for a wide range of…

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Code & Models

Repositories

Models

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cyrusyc/mace-universal
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Taxonomy

TopicsMachine Learning in Materials Science · Scientific Computing and Data Management