Optimizing Accuracy and Efficacy in Data-Driven Materials Discovery for the Solar Production of Hydrogen

Yihuang Xiong; Quinn T. Campbell; Julian Fanghanel; Catherine K. Badding; Huaiyu Wang; Nicole E. Kirchner-Hall; Monica J. Theibault; Iurii Timrov; Jared S. Mondschein; Kriti Seth; Rebecca Katz; Andrés Molina Villarino; Betül Pamuk; Megan E. Penrod; Mohammed M. Khan; Tiffany Rivera; Nathan C. Smith; Xavier Quintana; Paul Orbe; Craig J. Fennie; Senorpe Asem-Hiablie; James L. Young; Todd G. Deutsch; Matteo Cococcioni; Venkatraman Gopalan; Héctor D. Abruña; Raymond E. Schaak; Ismaila Dabo

doi:10.1039/d0ee02984j

Optimizing Accuracy and Efficacy in Data-Driven Materials Discovery for the Solar Production of Hydrogen

Yihuang Xiong
, Quinn T. Campbell
, Julian Fanghanel
, Catherine K. Badding
, Huaiyu Wang
, Nicole E. Kirchner-Hall
, Monica J. Theibault
, Iurii Timrov
, Jared S. Mondschein
, Kriti Seth
, Rebecca Katz
, Andrés Molina Villarino
, Betül Pamuk
, Megan E. Penrod
, Mohammed M. Khan
, Tiffany Rivera
, Nathan C. Smith
, Xavier Quintana
, Paul Orbe
, Craig J. Fennie

Senorpe Asem-Hiablie, James L. Young, Todd G. Deutsch, Matteo Cococcioni, Venkatraman Gopalan, Héctor D. Abruña, Raymond E. Schaak, Ismaila Dabo

Chemistry and Nanoscience

Pennsylvania State University
Sandia Laboratories Albuquerque
Cornell University
Swiss Federal Institute of Technology Lausanne
Northwestern University
University of Pavia

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

32 Scopus Citations

Abstract

The production of hydrogen fuels, via water splitting, is of practical relevance for meeting global energy needs and mitigating the environmental consequences of fossil-fuel-based transportation. Water photoelectrolysis has been proposed as a viable approach for generating hydrogen, provided that stable and inexpensive photocatalysts with conversion efficiencies over 10% can be discovered, synthesized at scale, and successfully deployed (Pinaud et al., Energy Environ. Sci., 2013, 6, 1983). While a number of first-principles studies have focused on the data-driven discovery of photocatalysts, in the absence of systematic experimental validation, the success rate of these predictions may be limited. We address this problem by developing a screening procedure with co-validation between experiment and theory to expedite the synthesis, characterization, and testing of the computationally predicted, most desirable materials. Starting with 70 150 compounds in the Materials Project database, the proposed protocol yielded 71 candidate photocatalysts, 11 of which were synthesized as single-phase materials. Experiments confirmed hydrogen generation and favorable band alignment for 6 of the 11 compounds, with the most promising ones belonging to the families of alkali and alkaline-earth indates and orthoplumbates. This study shows the accuracy of a nonempirical, Hubbard-corrected density-functional theory method to predict band gaps and band offsets at a fraction of the computational cost of hybrid functionals, and outlines an effective strategy to identify photocatalysts for solar hydrogen generation.

Original language	American English
Pages (from-to)	2335-2348
Number of pages	14
Journal	Energy and Environmental Science
Volume	14
Issue number	4
DOIs	https://doi.org/10.1039/d0ee02984j https://doi.org/10.1039/d0ee02984j
State	Published - Apr 2021

Bibliographical note

Publisher Copyright:
© The Royal Society of Chemistry.

NLR Publication Number

NREL/JA-5900-77697

Keywords

hydrogen
materials discovery
photocatalyst
photoelectrochemical
water splitting

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Xiong, Y., Campbell, Q. T., Fanghanel, J., Badding, C. K., Wang, H., Kirchner-Hall, N. E., Theibault, M. J., Timrov, I., Mondschein, J. S., Seth, K., Katz, R., Villarino, A. M., Pamuk, B., Penrod, M. E., Khan, M. M., Rivera, T., Smith, N. C., Quintana, X., Orbe, P., ... Dabo, I. (2021). Optimizing Accuracy and Efficacy in Data-Driven Materials Discovery for the Solar Production of Hydrogen. Energy and Environmental Science, 14(4), 2335-2348. https://doi.org/10.1039/d0ee02984j, https://doi.org/10.1039/d0ee02984j

@article{0f08f49cdd674b9e8300666908cf7f3a,

title = "Optimizing Accuracy and Efficacy in Data-Driven Materials Discovery for the Solar Production of Hydrogen",

abstract = "The production of hydrogen fuels, via water splitting, is of practical relevance for meeting global energy needs and mitigating the environmental consequences of fossil-fuel-based transportation. Water photoelectrolysis has been proposed as a viable approach for generating hydrogen, provided that stable and inexpensive photocatalysts with conversion efficiencies over 10\% can be discovered, synthesized at scale, and successfully deployed (Pinaud et al., Energy Environ. Sci., 2013, 6, 1983). While a number of first-principles studies have focused on the data-driven discovery of photocatalysts, in the absence of systematic experimental validation, the success rate of these predictions may be limited. We address this problem by developing a screening procedure with co-validation between experiment and theory to expedite the synthesis, characterization, and testing of the computationally predicted, most desirable materials. Starting with 70 150 compounds in the Materials Project database, the proposed protocol yielded 71 candidate photocatalysts, 11 of which were synthesized as single-phase materials. Experiments confirmed hydrogen generation and favorable band alignment for 6 of the 11 compounds, with the most promising ones belonging to the families of alkali and alkaline-earth indates and orthoplumbates. This study shows the accuracy of a nonempirical, Hubbard-corrected density-functional theory method to predict band gaps and band offsets at a fraction of the computational cost of hybrid functionals, and outlines an effective strategy to identify photocatalysts for solar hydrogen generation.",

keywords = "hydrogen, materials discovery, photocatalyst, photoelectrochemical, water splitting",

author = "Yihuang Xiong and Campbell, \{Quinn T.\} and Julian Fanghanel and Badding, \{Catherine K.\} and Huaiyu Wang and Kirchner-Hall, \{Nicole E.\} and Theibault, \{Monica J.\} and Iurii Timrov and Mondschein, \{Jared S.\} and Kriti Seth and Rebecca Katz and Villarino, \{Andr{\'e}s Molina\} and Bet{\"u}l Pamuk and Penrod, \{Megan E.\} and Khan, \{Mohammed M.\} and Tiffany Rivera and Smith, \{Nathan C.\} and Xavier Quintana and Paul Orbe and Fennie, \{Craig J.\} and Senorpe Asem-Hiablie and Young, \{James L.\} and Deutsch, \{Todd G.\} and Matteo Cococcioni and Venkatraman Gopalan and Abru{\~n}a, \{H{\'e}ctor D.\} and Schaak, \{Raymond E.\} and Ismaila Dabo",

note = "Publisher Copyright: {\textcopyright} The Royal Society of Chemistry.",

year = "2021",

month = apr,

doi = "10.1039/d0ee02984j",

language = "American English",

volume = "14",

pages = "2335--2348",

journal = "Energy and Environmental Science",

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publisher = "Royal Society of Chemistry",

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Xiong, Y, Campbell, QT, Fanghanel, J, Badding, CK, Wang, H, Kirchner-Hall, NE, Theibault, MJ, Timrov, I, Mondschein, JS, Seth, K, Katz, R, Villarino, AM, Pamuk, B, Penrod, ME, Khan, MM, Rivera, T, Smith, NC, Quintana, X, Orbe, P, Fennie, CJ, Asem-Hiablie, S, Young, JL , Deutsch, TG, Cococcioni, M, Gopalan, V, Abruña, HD, Schaak, RE & Dabo, I 2021, 'Optimizing Accuracy and Efficacy in Data-Driven Materials Discovery for the Solar Production of Hydrogen', Energy and Environmental Science, vol. 14, no. 4, pp. 2335-2348. https://doi.org/10.1039/d0ee02984j, https://doi.org/10.1039/d0ee02984j

TY - JOUR

T1 - Optimizing Accuracy and Efficacy in Data-Driven Materials Discovery for the Solar Production of Hydrogen

AU - Xiong, Yihuang

AU - Campbell, Quinn T.

AU - Fanghanel, Julian

AU - Badding, Catherine K.

AU - Wang, Huaiyu

AU - Kirchner-Hall, Nicole E.

AU - Theibault, Monica J.

AU - Timrov, Iurii

AU - Mondschein, Jared S.

AU - Seth, Kriti

AU - Katz, Rebecca

AU - Villarino, Andrés Molina

AU - Pamuk, Betül

AU - Penrod, Megan E.

AU - Khan, Mohammed M.

AU - Rivera, Tiffany

AU - Smith, Nathan C.

AU - Quintana, Xavier

AU - Orbe, Paul

AU - Fennie, Craig J.

AU - Asem-Hiablie, Senorpe

AU - Young, James L.

AU - Deutsch, Todd G.

AU - Cococcioni, Matteo

AU - Gopalan, Venkatraman

AU - Abruña, Héctor D.

AU - Schaak, Raymond E.

AU - Dabo, Ismaila

PY - 2021/4

Y1 - 2021/4

N2 - The production of hydrogen fuels, via water splitting, is of practical relevance for meeting global energy needs and mitigating the environmental consequences of fossil-fuel-based transportation. Water photoelectrolysis has been proposed as a viable approach for generating hydrogen, provided that stable and inexpensive photocatalysts with conversion efficiencies over 10% can be discovered, synthesized at scale, and successfully deployed (Pinaud et al., Energy Environ. Sci., 2013, 6, 1983). While a number of first-principles studies have focused on the data-driven discovery of photocatalysts, in the absence of systematic experimental validation, the success rate of these predictions may be limited. We address this problem by developing a screening procedure with co-validation between experiment and theory to expedite the synthesis, characterization, and testing of the computationally predicted, most desirable materials. Starting with 70 150 compounds in the Materials Project database, the proposed protocol yielded 71 candidate photocatalysts, 11 of which were synthesized as single-phase materials. Experiments confirmed hydrogen generation and favorable band alignment for 6 of the 11 compounds, with the most promising ones belonging to the families of alkali and alkaline-earth indates and orthoplumbates. This study shows the accuracy of a nonempirical, Hubbard-corrected density-functional theory method to predict band gaps and band offsets at a fraction of the computational cost of hybrid functionals, and outlines an effective strategy to identify photocatalysts for solar hydrogen generation.

AB - The production of hydrogen fuels, via water splitting, is of practical relevance for meeting global energy needs and mitigating the environmental consequences of fossil-fuel-based transportation. Water photoelectrolysis has been proposed as a viable approach for generating hydrogen, provided that stable and inexpensive photocatalysts with conversion efficiencies over 10% can be discovered, synthesized at scale, and successfully deployed (Pinaud et al., Energy Environ. Sci., 2013, 6, 1983). While a number of first-principles studies have focused on the data-driven discovery of photocatalysts, in the absence of systematic experimental validation, the success rate of these predictions may be limited. We address this problem by developing a screening procedure with co-validation between experiment and theory to expedite the synthesis, characterization, and testing of the computationally predicted, most desirable materials. Starting with 70 150 compounds in the Materials Project database, the proposed protocol yielded 71 candidate photocatalysts, 11 of which were synthesized as single-phase materials. Experiments confirmed hydrogen generation and favorable band alignment for 6 of the 11 compounds, with the most promising ones belonging to the families of alkali and alkaline-earth indates and orthoplumbates. This study shows the accuracy of a nonempirical, Hubbard-corrected density-functional theory method to predict band gaps and band offsets at a fraction of the computational cost of hybrid functionals, and outlines an effective strategy to identify photocatalysts for solar hydrogen generation.

KW - hydrogen

KW - materials discovery

KW - photocatalyst

KW - photoelectrochemical

KW - water splitting

UR - https://www.scopus.com/pages/publications/85104843091

U2 - 10.1039/d0ee02984j

DO - 10.1039/d0ee02984j

M3 - Article

AN - SCOPUS:85104843091

SN - 1754-5692

VL - 14

SP - 2335

EP - 2348

JO - Energy and Environmental Science

JF - Energy and Environmental Science

IS - 4

ER -

Optimizing Accuracy and Efficacy in Data-Driven Materials Discovery for the Solar Production of Hydrogen

Abstract

Bibliographical note

NLR Publication Number

Keywords

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