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Towards Pareto optimal high entropy hydrides via data-driven materials discovery

Witman, Matthew D.; Ling, Sanliang; Wadge, Matthew; Bouzidi, Anis; Pineda-Romero, Nayely; Clulow, Rebecca; Ek, Gustav; Chames, Jeffery M.; Allendorf, Emily J.; Agarwal, Sapan; Allendorf, Mark D.; Walker, Gavin S.; Grant, David M.; Sahlberg, Martin; Zlotea, Claudia; Stavila, Vitalie

Authors

Matthew D. Witman

Anis Bouzidi

Nayely Pineda-Romero

Rebecca Clulow

Gustav Ek

Jeffery M. Chames

Emily J. Allendorf

Sapan Agarwal

Mark D. Allendorf

Gavin S. Walker

DAVID GRANT DAVID.GRANT@NOTTINGHAM.AC.UK
Professor of Materials Science

Martin Sahlberg

Claudia Zlotea

Vitalie Stavila



Abstract

The ability to rapidly screen material performance in the vast space of high entropy alloys is of critical importance to efficiently identify optimal hydride candidates for various use cases. Given the prohibitive complexity of first principles simulations and large-scale sampling required to rigorously predict hydrogen equilibrium in these systems, we turn to compositional machine learning models as the most feasible approach to screen on the order of tens of thousands of candidate equimolar high entropy alloys (HEAs). Critically, we show that machine learning models can predict hydride thermodynamics and capacities with reasonable accuracy (e.g. a mean absolute error in desorption enthalpy prediction of ∼5 kJ molH2−1) and that explainability analyses capture the competing trade-offs that arise from feature interdependence. We can therefore elucidate the multi-dimensional Pareto optimal set of materials, i.e., where two or more competing objective properties can't be simultaneously improved by another material. This provides rapid and efficient down-selection of the highest priority candidates for more time-consuming density functional theory investigations and experimental validation. Various targets were selected from the predicted Pareto front (with saturation capacities approaching two hydrogen per metal and desorption enthalpy less than 60 kJ molH2−1) and were experimentally synthesized, characterized, and tested amongst an international collaboration group to validate the proposed novel hydrides. Additional top-predicted candidates are suggested to the community for future synthesis efforts, and we conclude with an outlook on improving the current approach for the next generation of computational HEA hydride discovery efforts.

Journal Article Type Article
Acceptance Date Jun 26, 2023
Online Publication Date Jul 7, 2023
Publication Date 2023-08
Deposit Date Jul 18, 2023
Publicly Available Date Jul 8, 2024
Journal Journal of Materials Chemistry A
Print ISSN 2050-7488
Electronic ISSN 2050-7496
Publisher Royal Society of Chemistry (RSC)
Peer Reviewed Peer Reviewed
Volume 11
Issue 29
Pages 15878-15888
DOI https://doi.org/10.1039/d3ta02323k
Keywords General Materials Science, Renewable Energy, Sustainability and the Environment, General Chemistry
Public URL https://nottingham-repository.worktribe.com/output/23005691
Publisher URL https://pubs.rsc.org/en/content/articlelanding/2023/ta/d3ta02323k

Files

This file is under embargo until Jul 8, 2024 due to copyright restrictions.




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