Discovery of complex oxides via automated experiments and data science

Creators: Yang, Lusann; Haber, Joel A.; Armstrong, Zan; Yang, Samuel J.; Kan, Kevin; Zhou, Lan; Richter, Matthias H.; Roat, Christopher; Wagner, Nicholas; Coram, Marc; Berndl, Marc; Riley, Patrick; Gregoire, John M.

Abstract

The quest to identify materials with tailored properties is increasingly expanding into high-order composition spaces, with a corresponding combinatorial explosion in the number of candidate materials. A key challenge is to discover regions in composition space where materials have novel properties. Traditional predictive models for material properties are not accurate enough to guide the search. Herein, we use high-throughput measurements of optical properties to identify novel regions in three-cation metal oxide composition spaces by identifying compositions whose optical trends cannot be explained by simple phase mixtures. We screen 376,752 distinct compositions from 108 three-cation oxide systems based on the cation elements Mg, Fe, Co, Ni, Cu, Y, In, Sn, Ce, and Ta. Data models for candidate phase diagrams and three-cation compositions with emergent optical properties guide the discovery of materials with complex phase-dependent properties, as demonstrated by the discovery of a Co-Ta-Sn substitutional alloy oxide with tunable transparency, catalytic activity, and stability in strong acid electrolytes. These results required close coupling of data validation to experiment design to generate a reliable end-to-end high-throughput workflow for accelerating scientific discovery.

Additional Information

© 2021 the Author(s). Published by PNAS. This open access article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND). Edited by Alexis T. Bell, University of California, Berkeley, CA, and approved August 2, 2021 (received for review April 16, 2021). This material is based on work performed by the Joint Center for Artificial Photosynthesis, a Department of Energy Energy Innovation Hub, supported through the US Department of Energy Office of Basic Energy Sciences under Award DE-SC0004993, which supported materials synthesis and characterization experiments. Google Applied Science supported the development and execution of the computational workflow as well as procurement of the hyperspectral microscope. Structural characterization and follow-up validation experiments were supported by the US Department of Energy Office of Basic Energy Sciences under Award DE-SC0020383. We are grateful for helpful discussions and guidance in the development of the computational workflow from Muskaan Goyal, Eric Christiansen, Edward A. Baltz, Derek Leong, Austin Blanco, and Mike Ando (Google Applied Science). We also appreciate the support of the experiment workflow from Edwin Soedarmadji (Caltech). We additionally appreciate helpful suggestions by David Fork and Michael Brenner (Google Applied Science). Data Availability: The optical absorption spectra, fitted phase diagrams, and mixture probabilities have been deposited in Google Cloud Storage (http://storage.googleapis.com/gresearch/metal-oxide-spectroscopy/README.txt; see SI Appendix for documentation and access instructions). Author contributions: L.Y., J.A.H., M.B., P.R., and J.M.G. designed research; L.Y., J.A.H., K.K., L.Z., and M.H.R. performed research; L.Y., J.A.H., Z.A., S.J.Y., C.R., M.C., M.B., P.R., and J.M.G. contributed new reagents/analytic tools; L.Y., J.A.H., N.W., and J.M.G. analyzed data; and L.Y., J.A.H., and J.M.G. wrote the paper. Competing interest statement: As listed in the affiliations, several authors are current or former employees of Google, a technology company that sells machine learning services as part of its business. This article is a PNAS Direct Submission. This article contains supporting information online at https://www.pnas.org/lookup/suppl/doi:10.1073/pnas.2106042118/-/DCSupplemental.

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