A foundation model for atomistic materials chemistry

Ilyes Batatia; Philipp Benner; Yuan Chiang; Alin M. Elena; Dávid P. Kovács; Janosh Riebesell; Xavier R. Advincula; Mark Asta; Matthew Avaylon; William J. Baldwin; Fabian Berger; Noam Bernstein; Arghya Bhowmik; Filippo Bigi; Samuel M. Blau; Vlad Cărare; Michele Ceriotti; Sanggyu Chong; James P. Darby; Sandip De; Flaviano Della Pia; Volker L. Deringer; Rokas Elijošius; Zakariya El-Machachi; Edvin Fako; Fabio Falcioni; Andrea C. Ferrari; John L.A. Gardner; Mikołaj 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; Cheuk Hin Ho; Stephan Hofmann; Christian Holm; 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 Magdău; 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; Tamás K. Stenczel; Christopher Sutton; Viktor Svahn; Thomas D. Swinburne; Jules Tilly; Cas van der Oord; Santiago Vargas; Eszter Varga-Umbrich; Tejs Vegge; Martin Vondrák; Yangshuai Wang; William C. Witt; Thomas Wolf; Fabian Zills; Gábor Csányi

doi:10.1063/5.0297006

A foundation model for atomistic materials chemistry

Ilyes Batatia
, Philipp Benner
, Yuan Chiang
, Alin M. Elena
, Dávid P. Kovács
, Janosh Riebesell
, Xavier R. Advincula
, Mark Asta
, Matthew Avaylon
, William J. Baldwin
, Fabian Berger
, Noam Bernstein
, Arghya Bhowmik
, Filippo Bigi
, Samuel M. Blau
, Vlad Cărare
, Michele Ceriotti
, Sanggyu Chong
, James P. Darby
, Sandip De

Flaviano Della Pia, Volker L. Deringer, Rokas Elijošius, Zakariya El-Machachi, Edvin Fako, Fabio Falcioni, Andrea C. Ferrari, John L.A. Gardner, Mikołaj 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, Cheuk Hin Ho, Stephan Hofmann, Christian Holm, 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 Magdău, 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, Tamás K. Stenczel, Christopher Sutton, Viktor Svahn, Thomas D. Swinburne, Jules Tilly, Cas van der Oord, Santiago Vargas, Eszter Varga-Umbrich, Tejs Vegge, Martin Vondrák, Yangshuai Wang, William C. Witt, Thomas Wolf, Fabian Zills, Gábor Csányi

Research output: Contribution to journal › Article › peer-review

16 Scopus citations

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 machine-learning (ML) force fields have largely been limited by (i) the substantial computational and human effort required to develop and validate 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 obtain reliable results much faster, and beginners face a lower barrier to entry. Foundation models thus represent a step toward democratizing the revolution in atomic-scale modeling that has been brought about by ML force fields.

Original language	English (US)
Article number	184110
Journal	Journal of Chemical Physics
Volume	163
Issue number	18
DOIs	https://doi.org/10.1063/5.0297006
State	Published - Nov 14 2025
Externally published	Yes

All Science Journal Classification (ASJC) codes

General Physics and Astronomy
Physical and Theoretical Chemistry

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10.1063/5.0297006

Cite this

Batatia, I., Benner, P., Chiang, Y., Elena, A. M., Kovács, D. P., Riebesell, J., Advincula, X. R., Asta, M., Avaylon, M., Baldwin, W. J., Berger, F., Bernstein, N., Bhowmik, A., Bigi, F., Blau, S. M., Cărare, V., Ceriotti, M., Chong, S., Darby, J. P., ... Csányi, G. (2025). A foundation model for atomistic materials chemistry. Journal of Chemical Physics, 163(18), Article 184110. https://doi.org/10.1063/5.0297006

@article{2048bc5a30574ce2b2e9ef392d6807fc,

title = "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 machine-learning (ML) force fields have largely been limited by (i) the substantial computational and human effort required to develop and validate 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 obtain reliable results much faster, and beginners face a lower barrier to entry. Foundation models thus represent a step toward democratizing the revolution in atomic-scale modeling that has been brought about by ML force fields.",

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

note = "Publisher Copyright: {\textcopyright} 2025 Author(s).",

year = "2025",

month = nov,

day = "14",

doi = "10.1063/5.0297006",

language = "English (US)",

volume = "163",

journal = "Journal of Chemical Physics",

issn = "0021-9606",

publisher = "American Institute of Physics",

number = "18",

}

Batatia, I, Benner, P, Chiang, Y, Elena, AM, Kovács, DP, Riebesell, J, Advincula, XR, Asta, M, Avaylon, M, Baldwin, WJ, Berger, F, Bernstein, N, Bhowmik, A, Bigi, F, Blau, SM, Cărare, V, Ceriotti, M, Chong, S, Darby, JP, De, S, Della Pia, F, Deringer, VL, Elijošius, R, El-Machachi, Z, Fako, E, Falcioni, F, Ferrari, AC, Gardner, JLA, Gawkowski, MJ, Genreith-Schriever, A, George, J, Goodall, REA, Grandel, J, Grey, CP, Grigorev, P, Han, S, Handley, W, Heenen, HH, Hermansson, K, Ho, CH, Hofmann, S, Holm, C, Jaafar, J, Jakob, KS, Jung, H, Kapil, V, Kaplan, AD, Karimitari, N, Kermode, JR, Kourtis, P, Kroupa, N, Kullgren, J, Kuner, MC, Kuryla, D, Liepuoniute, G, Lin, C, Margraf, JT, Magdău, IB, Michaelides, A, Moore, JH, Naik, AA, Niblett, SP, Norwood, SW, O’Neill, N, Ortner, C, Persson, KA, Reuter, K, Rosen, AS, Rosset, LAM, Schaaf, LL, Schran, C, Shi, BX, Sivonxay, E, Stenczel, TK, Sutton, C, Svahn, V, Swinburne, TD, Tilly, J, van der Oord, C, Vargas, S, Varga-Umbrich, E, Vegge, T, Vondrák, M, Wang, Y, Witt, WC, Wolf, T, Zills, F & Csányi, G 2025, 'A foundation model for atomistic materials chemistry', Journal of Chemical Physics, vol. 163, no. 18, 184110. https://doi.org/10.1063/5.0297006

TY - JOUR

T1 - A foundation model for atomistic materials chemistry

AU - Batatia, Ilyes

AU - Benner, Philipp

AU - Chiang, Yuan

AU - Elena, Alin M.

AU - Kovács, Dávid P.

AU - Riebesell, Janosh

AU - Advincula, Xavier R.

AU - Asta, Mark

AU - Avaylon, Matthew

AU - Baldwin, William J.

AU - Berger, Fabian

AU - Bernstein, Noam

AU - Bhowmik, Arghya

AU - Bigi, Filippo

AU - Blau, Samuel M.

AU - Cărare, Vlad

AU - Ceriotti, Michele

AU - Chong, Sanggyu

AU - Darby, James P.

AU - De, Sandip

AU - Della Pia, Flaviano

AU - Deringer, Volker L.

AU - Elijošius, Rokas

AU - El-Machachi, Zakariya

AU - Fako, Edvin

AU - Falcioni, Fabio

AU - Ferrari, Andrea C.

AU - Gardner, John L.A.

AU - Gawkowski, Mikołaj J.

AU - Genreith-Schriever, Annalena

AU - George, Janine

AU - Goodall, Rhys E.A.

AU - Grandel, Jonas

AU - Grey, Clare P.

AU - Grigorev, Petr

AU - Han, Shuang

AU - Handley, Will

AU - Heenen, Hendrik H.

AU - Hermansson, Kersti

AU - Ho, Cheuk Hin

AU - Hofmann, Stephan

AU - Holm, Christian

AU - Jaafar, Jad

AU - Jakob, Konstantin S.

AU - Jung, Hyunwook

AU - Kapil, Venkat

AU - Kaplan, Aaron D.

AU - Karimitari, Nima

AU - Kermode, James R.

AU - Kourtis, Panagiotis

AU - Kroupa, Namu

AU - Kullgren, Jolla

AU - Kuner, Matthew C.

AU - Kuryla, Domantas

AU - Liepuoniute, Guoda

AU - Lin, Chen

AU - Margraf, Johannes T.

AU - Magdău, Ioan Bogdan

AU - Michaelides, Angelos

AU - Moore, J. Harry

AU - Naik, Aakash A.

AU - Niblett, Samuel P.

AU - Norwood, Sam Walton

AU - O’Neill, Niamh

AU - Ortner, Christoph

AU - Persson, Kristin A.

AU - Reuter, Karsten

AU - Rosen, Andrew S.

AU - Rosset, Louise A.M.

AU - Schaaf, Lars L.

AU - Schran, Christoph

AU - Shi, Benjamin X.

AU - Sivonxay, Eric

AU - Stenczel, Tamás K.

AU - Sutton, Christopher

AU - Svahn, Viktor

AU - Swinburne, Thomas D.

AU - Tilly, Jules

AU - van der Oord, Cas

AU - Vargas, Santiago

AU - Varga-Umbrich, Eszter

AU - Vegge, Tejs

AU - Vondrák, Martin

AU - Wang, Yangshuai

AU - Witt, William C.

AU - Wolf, Thomas

AU - Zills, Fabian

AU - Csányi, Gábor

PY - 2025/11/14

Y1 - 2025/11/14

N2 - 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 machine-learning (ML) force fields have largely been limited by (i) the substantial computational and human effort required to develop and validate 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 obtain reliable results much faster, and beginners face a lower barrier to entry. Foundation models thus represent a step toward democratizing the revolution in atomic-scale modeling that has been brought about by ML force fields.

AB - 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 machine-learning (ML) force fields have largely been limited by (i) the substantial computational and human effort required to develop and validate 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 obtain reliable results much faster, and beginners face a lower barrier to entry. Foundation models thus represent a step toward democratizing the revolution in atomic-scale modeling that has been brought about by ML force fields.

UR - https://www.scopus.com/pages/publications/105021402106

UR - https://www.scopus.com/pages/publications/105021402106#tab=citedBy

U2 - 10.1063/5.0297006

DO - 10.1063/5.0297006

M3 - Article

C2 - 41230846

AN - SCOPUS:105021402106

SN - 0021-9606

VL - 163

JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

IS - 18

M1 - 184110

ER -

A foundation model for atomistic materials chemistry

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