A foundation model for atomistic materials chemistry

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

doi:10.48550/arxiv.2401.00096

preprintarXiv (Cornell University)Dec 29, 2023GREEN OA

A foundation model for atomistic materials chemistry

BIBatatia, IlyesPBPhilipp Benner YCYuan Chiang AMAlin M. Elena DPDávid Péter Kovács

Indexed inarxivdatacite

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…

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Topics & keywords

Topics

Keywords

Transferability
Foundation (evidence)
Computer science
Ab initio
Molecular dynamics
Statistical physics
Nanotechnology
Computational science

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Funding

EA
Engineering and Physical Sciences Research Council
Award: EP/V028537/1