Atomate2: modular workflows for materials science

Ganose, Alex M.; Sahasrabuddhe, Hrushikesh; Asta, Mark; Beck, Kevin; Biswas, Tathagata; Bonkowski, Alexander; Bustamante, Joana; Chen, Xin; Chiang, Yuan; Chrzan, Daryl C.; Clary, Jacob; Cohen, Orion A.; Ertural, Christina; Gallant, Max C.; George, Janine; Gerits, Sophie; Goodall, Rhys E. A.; Guha, Rishabh D.; Hautier, Geoffroy; Horton, Matthew

doi:10.1039/d5dd00019j

Atomate2: modular workflows for materials science

Ganose, Alex M.

;

Sahasrabuddhe, Hrushikesh

;

Asta, Mark

;

Beck, Kevin

;

Jain, Anubhav

;et.al.

(2025) Digital Discovery — Vol. 4, n° 7, p. 1944-1973 (2025)

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Authors

Ganose, Alex M.Department of Chemistry, Imperial College London, London W12 0BZ, UK
Author
Sahasrabuddhe, HrushikeshDepartment of Materials Science and Engineering, University of California, Berkeley, California, USA
Author
Asta, MarkDepartment of Materials Science and Engineering, University of California, Berkeley, California, USA
Author
Beck, KevinProgram in Applied Mathematics, University of Arizona, 617 N. Santa Rita, Tucson, Arizona 85721, USA
Author
Biswas, TathagataUCLouvain
Author
Petretto, GuidoUCLouvain
Author
Ricci, FrancescoUCLouvain
Author
Rignanese, Gian-MarcoUCLouvain
Author
Trinquet, VictorUCLouvain
Author
Jain, AnubhavEnergy Technologies Area, Lawrence Berkeley National Laboratory, Berkeley, CA 94720, USA
Author

Abstract

High-throughput density functional theory (DFT) calculations have become a vital element of computational materials science, enabling materials screening, property database generation, and training of “universal” machine learning models. While several software frameworks have emerged to support these computational efforts, new developments such as machine learned force fields have increased demands for more flexible and programmable workflow solutions. This manuscript introduces atomate2, a comprehensive evolution of our original atomate framework, designed to address existing limitations in computational materials research infrastructure. Key features include the support for multiple electronic structure packages and interoperability between them, along with generalizable workflows that can be written in an abstract form irrespective of the DFT package or machine learning force field used within them. Our hope is that atomate2's improved usability and extensibility can reduce technical barriers for high-throughput research workflows and facilitate the rapid adoption of emerging methods in computational material science.

Affiliations

UCLouvainSST/IMCN/MODL - Modelling

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Ganose, A. M., Sahasrabuddhe, H., Asta, M., Beck, K., Biswas, T., Bonkowski, A., Bustamante, J., Chen, X., Chiang, Y., Chrzan, D. C., Clary, J., Cohen, O. A., Ertural, C., Gallant, M. C., George, J., Gerits, S., Goodall, R. E. A., Guha, R. D., Hautier, G., et al. (2025). Atomate2: modular workflows for materials science. Digital Discovery, 4(7), 1944-1973. https://doi.org/10.1039/d5dd00019j (Original work published 2025)