Matbench Discovery is an interactive leaderboard that ranks ML interatomic potentials across crystal stability prediction, geometry optimization, phonons and thermal conductivity, molecular dynamics, and diatomic potential-energy curves.
We rank 20+ models covering multiple methodologies including graph neural network (GNN) interatomic potentials, GNN one-shot predictors, iterative Bayesian optimizers and random forests with shallow-learning structure fingerprints.
The benchmark exposes accuracy, robustness, and computational-cost trade-offs across these tasks to help users choose models for static and finite-temperature materials simulations.
📖 Important: In Matbench Discovery, the convex hull used to evaluate stability is constructed from DFT reference energies, not from model predictions. This differs from some other benchmarking approaches and has important implications for metric interpretation. See
/tasks/discoveryfor more information.
To cite Matbench Discovery, use:
Riebesell, J., Goodall, R.E.A., Benner, P. et al. A framework to evaluate machine learning crystal stability predictions. Nat Mach Intell 7, 836–847 (2025). https://doi.org/10.1038/s42256-025-01055-1
We welcome new models additions to the leaderboard through GitHub PRs. See the contributing guide for details and ask support questions via GitHub discussion.
Disclaimer: We evaluate how accurately ML models predict several material properties like thermodynamic stability, thermal conductivity, and atomic positions, in all cases using PBE DFT as reference data. Although these properties are important for high-throughput materials discovery, the ranking cannot give a complete picture of a model's overall ability to drive materials research. A high ranking does not constitute endorsement by the Materials Project.