Constructing an Adaptive Heterojunction as a Highly Active Catalyst for the Oxygen Evolution Reaction

Xiao Ren; Chao Wei; Yuanmiao Sun; Xiaozhi Liu; Fanqi Meng; Xiaoxia Meng; Shengnan Sun; Shibo Xi; Yonghua Du; Zhuanfang Bi; Guangyi Shang; Adrian C. Fisher; Lin Gu; Zhichuan J. Xu

doi:10.1002/adma.202001292

Constructing an Adaptive Heterojunction as a Highly Active Catalyst for the Oxygen Evolution Reaction

Xiao Ren, Chao Wei, Yuanmiao Sun, Xiaozhi Liu, Fanqi Meng, Xiaoxia Meng, Shengnan Sun, Shibo Xi, Yonghua Du, Zhuanfang Bi, Guangyi Shang, Adrian C. Fisher, Lin Gu, Zhichuan J. Xu^*

^*Corresponding author for this work

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

171 Citations (Scopus)

Abstract

Electrochemical water splitting is of prime importance to green energy technology. Particularly, the reaction at the anode side, namely the oxygen evolution reaction (OER), requires a high overpotential associated with O-O bond formation, which dominates the energy-efficiency of the whole process. Activating the anionic redox chemistry of oxygen in metal oxides, which involves the formation of superoxo/peroxo-like (O₂)ⁿ⁻, commonly occurs in most highly active catalysts during the OER process. In this study, a highly active catalyst is designed: electrochemically delithiated LiNiO₂, which facilitates the formation of superoxo/peroxo-like (O₂)ⁿ⁻ species, i.e., NiOO*, for enhancing OER activity. The OER-induced surface reconstruction builds an adaptive heterojunction, where NiOOH grows on delithiated LiNiO₂ (delithiated-LiNiO₂/NiOOH). At this junction, the lithium vacancies within the delithiated LiNiO₂ optimize the electronic structure of the surface NiOOH to form stable NiOO* species, which enables better OER activity. This finding provides new insight for designing highly active catalysts with stable superoxo-like/peroxo-like (O₂)ⁿ⁻ for water oxidation.

Original language	English
Article number	2001292
Journal	Advanced Materials
Volume	32
Issue number	30
DOIs	https://doi.org/10.1002/adma.202001292
Publication status	Published - Jul 1 2020
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

ASJC Scopus Subject Areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

Keywords

adaptive junctions
cycling
delithiation
oxygen evolution
reconstruction

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/adma.202001292

Cite this

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title = "Constructing an Adaptive Heterojunction as a Highly Active Catalyst for the Oxygen Evolution Reaction",

abstract = "Electrochemical water splitting is of prime importance to green energy technology. Particularly, the reaction at the anode side, namely the oxygen evolution reaction (OER), requires a high overpotential associated with O-O bond formation, which dominates the energy-efficiency of the whole process. Activating the anionic redox chemistry of oxygen in metal oxides, which involves the formation of superoxo/peroxo-like (O2)n−, commonly occurs in most highly active catalysts during the OER process. In this study, a highly active catalyst is designed: electrochemically delithiated LiNiO2, which facilitates the formation of superoxo/peroxo-like (O2)n− species, i.e., NiOO*, for enhancing OER activity. The OER-induced surface reconstruction builds an adaptive heterojunction, where NiOOH grows on delithiated LiNiO2 (delithiated-LiNiO2/NiOOH). At this junction, the lithium vacancies within the delithiated LiNiO2 optimize the electronic structure of the surface NiOOH to form stable NiOO* species, which enables better OER activity. This finding provides new insight for designing highly active catalysts with stable superoxo-like/peroxo-like (O2)n− for water oxidation.",

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author = "Xiao Ren and Chao Wei and Yuanmiao Sun and Xiaozhi Liu and Fanqi Meng and Xiaoxia Meng and Shengnan Sun and Shibo Xi and Yonghua Du and Zhuanfang Bi and Guangyi Shang and Fisher, {Adrian C.} and Lin Gu and Xu, {Zhichuan J.}",

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AU - Ren, Xiao

AU - Wei, Chao

AU - Sun, Yuanmiao

AU - Liu, Xiaozhi

AU - Meng, Fanqi

AU - Meng, Xiaoxia

AU - Sun, Shengnan

AU - Xi, Shibo

AU - Du, Yonghua

AU - Bi, Zhuanfang

AU - Shang, Guangyi

AU - Fisher, Adrian C.

AU - Gu, Lin

AU - Xu, Zhichuan J.

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AB - Electrochemical water splitting is of prime importance to green energy technology. Particularly, the reaction at the anode side, namely the oxygen evolution reaction (OER), requires a high overpotential associated with O-O bond formation, which dominates the energy-efficiency of the whole process. Activating the anionic redox chemistry of oxygen in metal oxides, which involves the formation of superoxo/peroxo-like (O2)n−, commonly occurs in most highly active catalysts during the OER process. In this study, a highly active catalyst is designed: electrochemically delithiated LiNiO2, which facilitates the formation of superoxo/peroxo-like (O2)n− species, i.e., NiOO*, for enhancing OER activity. The OER-induced surface reconstruction builds an adaptive heterojunction, where NiOOH grows on delithiated LiNiO2 (delithiated-LiNiO2/NiOOH). At this junction, the lithium vacancies within the delithiated LiNiO2 optimize the electronic structure of the surface NiOOH to form stable NiOO* species, which enables better OER activity. This finding provides new insight for designing highly active catalysts with stable superoxo-like/peroxo-like (O2)n− for water oxidation.

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Constructing an Adaptive Heterojunction as a Highly Active Catalyst for the Oxygen Evolution Reaction

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

UN SDGs

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