Exceptional oxygen evolution reactivities on CaCoO3 and SrCoO3

Xiang Li; Hao Wang; Zhiming Cui; Yutao Li; Sen Xin; Jianshi Zhou; Youwen Long; Changqing Jin; John B. Goodenough

doi:10.1126/sciadv.aav6262

Exceptional oxygen evolution reactivities on CaCoO₃ and SrCoO₃

Xiang Li, Hao Wang, Zhiming Cui, Yutao Li^*, Sen Xin, Jianshi Zhou, Youwen Long, Changqing Jin, John B. Goodenough

^*Corresponding author for this work

School of Physics

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

165 Citations (Scopus)

Abstract

We investigated the roles of covalent bonding, separation of surface oxygen, and electrolyte pH on the oxygen evolution reaction (OER) on transition metal oxides by comparing catalytic onset potentials and activities of CaCoO₃ and SrCoO₃. Both cubic, metallic perovskites have similar Co^IV intermediate spin states and onset potentials, but a substantially smaller lattice parameter and shorter surface oxygen separation make CaCoO₃ a more stable catalyst with increased OER activity. The onset potentials are similar, occurring where H⁺ is removed from surface -OH⁻, but two competing surface reactions determine the catalytic activity. In one, the surface -O⁻ is attacked by electrolyte OH⁻ to form the surface -OOH⁻; in the other, two -O⁻ form a surface peroxide ion and an oxygen vacancy with electrolyte OH⁻ attacking the oxygen vacancy. The second pathway can be faster if the surface oxygen separation is smaller.

Original language	English
Article number	eaav6262
Journal	Science advances
Volume	5
Issue number	8
DOIs	https://doi.org/10.1126/sciadv.aav6262
Publication status	Published - 9 Aug 2019

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title = "Exceptional oxygen evolution reactivities on CaCoO3 and SrCoO3 ",

abstract = "We investigated the roles of covalent bonding, separation of surface oxygen, and electrolyte pH on the oxygen evolution reaction (OER) on transition metal oxides by comparing catalytic onset potentials and activities of CaCoO3 and SrCoO3. Both cubic, metallic perovskites have similar CoIV intermediate spin states and onset potentials, but a substantially smaller lattice parameter and shorter surface oxygen separation make CaCoO3 a more stable catalyst with increased OER activity. The onset potentials are similar, occurring where H+ is removed from surface -OH−, but two competing surface reactions determine the catalytic activity. In one, the surface -O− is attacked by electrolyte OH− to form the surface -OOH−; in the other, two -O− form a surface peroxide ion and an oxygen vacancy with electrolyte OH− attacking the oxygen vacancy. The second pathway can be faster if the surface oxygen separation is smaller.",

author = "Xiang Li and Hao Wang and Zhiming Cui and Yutao Li and Sen Xin and Jianshi Zhou and Youwen Long and Changqing Jin and Goodenough, {John B.}",

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AU - Li, Xiang

AU - Wang, Hao

AU - Cui, Zhiming

AU - Li, Yutao

AU - Xin, Sen

AU - Zhou, Jianshi

AU - Long, Youwen

AU - Jin, Changqing

AU - Goodenough, John B.

N1 - Publisher Copyright: Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).

PY - 2019/8/9

Y1 - 2019/8/9

N2 - We investigated the roles of covalent bonding, separation of surface oxygen, and electrolyte pH on the oxygen evolution reaction (OER) on transition metal oxides by comparing catalytic onset potentials and activities of CaCoO3 and SrCoO3. Both cubic, metallic perovskites have similar CoIV intermediate spin states and onset potentials, but a substantially smaller lattice parameter and shorter surface oxygen separation make CaCoO3 a more stable catalyst with increased OER activity. The onset potentials are similar, occurring where H+ is removed from surface -OH−, but two competing surface reactions determine the catalytic activity. In one, the surface -O− is attacked by electrolyte OH− to form the surface -OOH−; in the other, two -O− form a surface peroxide ion and an oxygen vacancy with electrolyte OH− attacking the oxygen vacancy. The second pathway can be faster if the surface oxygen separation is smaller.

AB - We investigated the roles of covalent bonding, separation of surface oxygen, and electrolyte pH on the oxygen evolution reaction (OER) on transition metal oxides by comparing catalytic onset potentials and activities of CaCoO3 and SrCoO3. Both cubic, metallic perovskites have similar CoIV intermediate spin states and onset potentials, but a substantially smaller lattice parameter and shorter surface oxygen separation make CaCoO3 a more stable catalyst with increased OER activity. The onset potentials are similar, occurring where H+ is removed from surface -OH−, but two competing surface reactions determine the catalytic activity. In one, the surface -O− is attacked by electrolyte OH− to form the surface -OOH−; in the other, two -O− form a surface peroxide ion and an oxygen vacancy with electrolyte OH− attacking the oxygen vacancy. The second pathway can be faster if the surface oxygen separation is smaller.

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Exceptional oxygen evolution reactivities on CaCoO₃ and SrCoO₃

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