A foundation model for atomistic materials chemistry

Ilyes Batatia; Philipp Benner; Chiang Yuan; A. Elena; D. Kov'acs; Janosh Riebesell; Xavier R Advincula; M. Asta; William J. Baldwin; Noam Bernstein; Arghya Bhowmik; Samuel M. Blau; Vlad Cuarare; James P Darby; Sandip De; Flaviano Della Pia; Volker L. Deringer; Rokas Elijovsius; Zakariya El-Machachi; Edvin Fako; Andrea C. Ferrari; A. Genreith‐Schriever; Janine George; Rhys E. A. Goodall; Clare P. Grey; Shuang Han; Will Handley; H. H. Heenen; K. Hermansson; Christian Holm; Jad Jaafar; Stephan Hofmann; Konstantin S. Jakob; Hyunwook Jung; V. Kapil; Aaron D. Kaplan; Nima Karimitari; Namu Kroupa; J. Kullgren; Matthew C Kuner; Domantas Kuryla; Guoda Liepuoniute; Johannes T. Margraf; Ioan B Magduau; A. Michaelides; J. H. Moore; A. Naik; Samuel P Niblett; Sam Walton Norwood; Niamh O'Neill; Christoph Ortner; Kristin A. Persson; K. Reuter; Andrew S. Rosen; Lars L. Schaaf; Christoph Schran; Eric Sivonxay; Tamás K Stenczel; Viktor Svahn; Christopher Sutton; Cas van der Oord; Eszter Varga-Umbrich; T. Vegge; Martin Vondr'ak; Yangshuai Wang; William C. Witt; Fabian Zills; G'abor Cs'anyi

Paper

A foundation model for atomistic materials chemistry

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 molecules and materials. We demonstrate the power of the MACE-MP-0 model - and its qualitative and at times quantitative accuracy - on a diverse set of problems in the physical sciences, including properties of solids, liquids, gases, chemical reactions, interfaces and even the dynamics of a small protein. The model can be applied out of the box as a starting or "foundation" model for any atomistic system of interest and, when desired, can be fine-tuned on just a handful of application-specific data points to reach ab initio accuracy. Establishing that a stable force-field model can cover almost all materials changes atomistic modeling in a fundamental way: experienced users get reliable results much faster, and beginners face a lower barrier to entry. Foundation models thus represent a step towards democratising the revolution in atomic-scale modeling that has been brought about by ML force fields.