Abstract
Unravelling the connections between microscopic structure, emergent physical properties and slow dynamics has long been a challenge when studying the glass transition. The absence of clear visible structural order in amorphous configurations complicates the identification of the key physical mechanisms underpinning slow dynamics. The difficulty in sampling equilibrated configurations at low temperatures hampers thorough numerical and theoretical investigations. We explore the potential of machine learning (ML) techniques to face these challenges, building on the algorithms that have revolutionized computer vision and image recognition. We present both successful ML applications and open problems for the future, such as transferability and interpretability of ML approaches. To foster a collaborative community effort, we also highlight the ‘GlassBench’ dataset, which provides simulation data and benchmarks for both 2D and 3D glass formers. We compare the performance of emerging ML methodologies, in line with benchmarking practices in image and text recognition. Our goal is to provide guidelines for the development of ML techniques in systems displaying slow dynamics and inspire new directions to improve our theoretical understanding of glassy liquids.
| Original language | English |
|---|---|
| Pages (from-to) | 91-104 |
| Number of pages | 14 |
| Journal | Nature Reviews Physics |
| Volume | 7 |
| Issue number | 2 |
| Early online date | 6 Jan 2025 |
| DOIs | |
| Publication status | Published - 2025 |
Bibliographical note
Publisher Copyright:© Springer Nature Limited 2025.
Funding
This paper originates from discussions and interactions at the AISSAI (AI for science, science for AI) workshop on 'Machine Learning Glasses' held in November 2022 in Paris. This workshop was organized by G.B., L.B. and G.J. The authors thank all participants for their attendance, discussions and feedback, in particular A. Banerjee, L. Janssen, M. Ruiz Garcia, S. Patinet, C. Scalliet, D. Richard, J. Rottler, O. Dauchot and O. Kukharenko for their valuable contributions. F.S.P. is supported by a public grant overseen by the French National Research Agency (ANR) through the programme UDOPIA, project funded by the ANR-20-THIA-0013-01. F.S.P. was granted access to the HPC resources of IDRIS under the allocation 2022-AD011014066 made by GENCI. H.S. acknowledges computational resources provided by 'Joint Usage/Research Center for Interdisciplinary Large-scale Information Infrastructures (JHPCN)' and 'High Performance Computing Infrastructure (HPCI)' in Japan (project ID: jh230064). A.J.L. is supported by the Simons Foundation via the Investigator Award #327939. In addition, A.J.L. thanks CCB at the Flatiron Institute and the Isaac Newton Institute for Mathematical Sciences under the programme 'New Statistical Physics in Living Matter' (EPSRC grant EP/R014601/1) for the support and hospitality. This work was supported by a grant from the Simons Foundation (#454933 to L.B., #454935 to G.B.). G.B. acknowledges funding from the French government under the management of Agence Nationale de la Recherche as part of the 'Investissements d'avenir' programme, reference ANR-19-P3IA-0001 (PRAIRIE 3IA Institute).
| Funders | Funder number |
|---|---|
| French National Research Agency (ANR) | ANR-20-THIA-0013-01 |
| Joint Usage/Research Center for Interdisciplinary Large-scale Information Infrastructures (JHPCN) | |
| High Performance Computing Infrastructure (HPCI)' in Japan | jh230064 |
| Simons Foundation via the Investigator Award | 327939 |
| CCB at the Flatiron Institute | |
| Isaac Newton Institute for Mathematical Sciences under the programme 'New Statistical Physics in Living Matter' | EP/R014601/1 |
| Simons Foundation | 454933, 454935 |
| French government under the management of Agence Nationale de la Recherche as part of the 'Investissements d'avenir' programme | ANR-19-P3IA-0001 |