Atomate2: Modular Workflows for Materials Science

Alex Ganose; Hrushikesh Sahasrabuddhe; Mark Asta; Kevin Beck; Tathagata Biswas; Alexander Bonkowski; Joana Bustamante; Xin Chen; Yuan Chiang; Daryl Chrzan; Jacob Clary; Orion Cohen; Christina Ertural; Max Gallant; Janine George; Sophie Gerits; Rhys Goodall; Rishabh Guha; Geoffroy Hautier; Matthew Horton; T. J. Inizan; Aaron Kaplan; Ryan Kingsbury; Matthew Kuner; Bryant Li; Xavier Linn; Matthew McDermott; Rohith Mohanakrishnan; Aakash Naik; Jeffrey Neaton; Shehan Parmar; Kristin Persson; Guido Petretto; Thomas Purcell; Francesco Ricci; Benjamin Rich; Janosh Riebesell; Gian-Marco Rignanese; Andrew Rosen; Matthias Scheffler; Jonathan Schmidt; Jimmy-Xuan Shen; Andrei Sobolev; Ravishankar Sundararaman; Cooper Tezak; Victor Trinquet; Joel Varley; Derek Vigil-Fowler; Duo Wang; David Waroquiers; Mingjian Wen; Han Yang; Hui Zheng; Jiongzhi Zheng; Zhuoying Zhu; Anubhav Jain

doi:10.1039/D5DD00019J

Atomate2: Modular Workflows for Materials Science

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

T. J. Inizan, Aaron Kaplan, Ryan Kingsbury, Matthew Kuner, Bryant Li, Xavier Linn, Matthew McDermott, Rohith Mohanakrishnan, Aakash Naik, Jeffrey Neaton, Shehan Parmar, Kristin Persson, Guido Petretto, Thomas Purcell, Francesco Ricci, Benjamin Rich, Janosh Riebesell, Gian-Marco Rignanese, Andrew Rosen, Matthias Scheffler, Jonathan Schmidt, Jimmy-Xuan Shen, Andrei Sobolev, Ravishankar Sundararaman, Cooper Tezak, Victor Trinquet, Joel Varley, Derek Vigil-Fowler, Duo Wang, David Waroquiers, Mingjian Wen, Han Yang, Hui Zheng, Jiongzhi Zheng, Zhuoying Zhu, Anubhav Jain

Computational Science

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

13 Scopus Citations

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.

Original language	American English
Pages (from-to)	1944-1973
Number of pages	30
Journal	Digital Discovery
Volume	4
Issue number	7
DOIs	https://doi.org/10.1039/D5DD00019J
State	Published - 2025

NLR Publication Number

NREL/JA-2C00-96058

Keywords

atomate2
high-throughput density functional theory
software

Access to Document

10.1039/D5DD00019J

https://www.nrel.gov/docs/fy25osti/96058.pdf

Cite this

Ganose, A., Sahasrabuddhe, H., Asta, M., Beck, K., Biswas, T., Bonkowski, A., Bustamante, J., Chen, X., Chiang, Y., Chrzan, D., Clary, J., Cohen, O., Ertural, C., Gallant, M., George, J., Gerits, S., Goodall, R., Guha, R., Hautier, G., ... Jain, A. (2025). Atomate2: Modular Workflows for Materials Science. Digital Discovery, 4(7), 1944-1973. https://doi.org/10.1039/D5DD00019J

@article{0b00c28d95034e01b7aefd685815e051,

title = "Atomate2: Modular Workflows for Materials Science",

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.",

keywords = "atomate2, high-throughput density functional theory, software",

author = "Alex Ganose and Hrushikesh Sahasrabuddhe and Mark Asta and Kevin Beck and Tathagata Biswas and Alexander Bonkowski and Joana Bustamante and Xin Chen and Yuan Chiang and Daryl Chrzan and Jacob Clary and Orion Cohen and Christina Ertural and Max Gallant and Janine George and Sophie Gerits and Rhys Goodall and Rishabh Guha and Geoffroy Hautier and Matthew Horton and Inizan, \{T. J.\} and Aaron Kaplan and Ryan Kingsbury and Matthew Kuner and Bryant Li and Xavier Linn and Matthew McDermott and Rohith Mohanakrishnan and Aakash Naik and Jeffrey Neaton and Shehan Parmar and Kristin Persson and Guido Petretto and Thomas Purcell and Francesco Ricci and Benjamin Rich and Janosh Riebesell and Gian-Marco Rignanese and Andrew Rosen and Matthias Scheffler and Jonathan Schmidt and Jimmy-Xuan Shen and Andrei Sobolev and Ravishankar Sundararaman and Cooper Tezak and Victor Trinquet and Joel Varley and Derek Vigil-Fowler and Duo Wang and David Waroquiers and Mingjian Wen and Han Yang and Hui Zheng and Jiongzhi Zheng and Zhuoying Zhu and Anubhav Jain",

year = "2025",

doi = "10.1039/D5DD00019J",

language = "American English",

volume = "4",

pages = "1944--1973",

journal = "Digital Discovery",

issn = "2635-098X",

publisher = "Royal Society of Chemistry",

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Ganose, A, Sahasrabuddhe, H, Asta, M, Beck, K, Biswas, T, Bonkowski, A, Bustamante, J, Chen, X, Chiang, Y, Chrzan, D, Clary, J, Cohen, O, Ertural, C, Gallant, M, George, J, Gerits, S, Goodall, R, Guha, R, Hautier, G, Horton, M, Inizan, TJ, Kaplan, A, Kingsbury, R, Kuner, M, Li, B, Linn, X, McDermott, M, Mohanakrishnan, R, Naik, A, Neaton, J, Parmar, S, Persson, K, Petretto, G, Purcell, T, Ricci, F, Rich, B, Riebesell, J, Rignanese, G-M, Rosen, A, Scheffler, M, Schmidt, J, Shen, J-X, Sobolev, A, Sundararaman, R, Tezak, C, Trinquet, V, Varley, J, Vigil-Fowler, D, Wang, D, Waroquiers, D, Wen, M, Yang, H, Zheng, H, Zheng, J, Zhu, Z & Jain, A 2025, 'Atomate2: Modular Workflows for Materials Science', Digital Discovery, vol. 4, no. 7, pp. 1944-1973. https://doi.org/10.1039/D5DD00019J

TY - JOUR

T1 - Atomate2: Modular Workflows for Materials Science

AU - Ganose, Alex

AU - Sahasrabuddhe, Hrushikesh

AU - Asta, Mark

AU - Beck, Kevin

AU - Biswas, Tathagata

AU - Bonkowski, Alexander

AU - Bustamante, Joana

AU - Chen, Xin

AU - Chiang, Yuan

AU - Chrzan, Daryl

AU - Clary, Jacob

AU - Cohen, Orion

AU - Ertural, Christina

AU - Gallant, Max

AU - George, Janine

AU - Gerits, Sophie

AU - Goodall, Rhys

AU - Guha, Rishabh

AU - Hautier, Geoffroy

AU - Horton, Matthew

AU - Inizan, T. J.

AU - Kaplan, Aaron

AU - Kingsbury, Ryan

AU - Kuner, Matthew

AU - Li, Bryant

AU - Linn, Xavier

AU - McDermott, Matthew

AU - Mohanakrishnan, Rohith

AU - Naik, Aakash

AU - Neaton, Jeffrey

AU - Parmar, Shehan

AU - Persson, Kristin

AU - Petretto, Guido

AU - Purcell, Thomas

AU - Ricci, Francesco

AU - Rich, Benjamin

AU - Riebesell, Janosh

AU - Rignanese, Gian-Marco

AU - Rosen, Andrew

AU - Scheffler, Matthias

AU - Schmidt, Jonathan

AU - Shen, Jimmy-Xuan

AU - Sobolev, Andrei

AU - Sundararaman, Ravishankar

AU - Tezak, Cooper

AU - Trinquet, Victor

AU - Varley, Joel

AU - Vigil-Fowler, Derek

AU - Wang, Duo

AU - Waroquiers, David

AU - Wen, Mingjian

AU - Yang, Han

AU - Zheng, Hui

AU - Zheng, Jiongzhi

AU - Zhu, Zhuoying

AU - Jain, Anubhav

PY - 2025

Y1 - 2025

N2 - 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.

AB - 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.

KW - atomate2

KW - high-throughput density functional theory

KW - software

U2 - 10.1039/D5DD00019J

DO - 10.1039/D5DD00019J

M3 - Article

SN - 2635-098X

VL - 4

SP - 1944

EP - 1973

JO - Digital Discovery

JF - Digital Discovery

IS - 7

ER -

Atomate2: Modular Workflows for Materials Science

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Keywords

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