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

Overview

Journal Adv Mater

Date 2020 Jun 23

PMID 32567128

Citations 13

Authors

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

Affiliations

Soon will be listed here.

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 (O ) , commonly occurs in most highly active catalysts during the OER process. In this study, a highly active catalyst is designed: electrochemically delithiated LiNiO , which facilitates the formation of superoxo/peroxo-like (O ) species, i.e., NiOO*, for enhancing OER activity. The OER-induced surface reconstruction builds an adaptive heterojunction, where NiOOH grows on delithiated LiNiO (delithiated-LiNiO /NiOOH). At this junction, the lithium vacancies within the delithiated LiNiO 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 (O ) for water oxidation.

Citing Articles

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A Review of Surface Reconstruction and Transformation of 3d Transition-Metal (oxy)Hydroxides and Spinel-Type Oxides during the Oxygen Evolution Reaction.

He B, Bai F, Jain P, Li T Small. 2025; 21(10):e2411479.

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Deciphering Water Oxidation Catalysts: The Dominant Role of Surface Chemistry over Reconstruction Degree in Activity Promotion.

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Exploring the Mechanisms of LiNiO Cathode Degradation by the Electrolyte Interfacial Deprotonation Reaction.

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Direct Identification of O─O Bond Formation Through Three-Step Oxidation During Water Splitting by Operando Soft X-ray Absorption Spectroscopy.

Huang Y, Wu Y, Lu Y, Chen J, Lin H, Chen C Adv Sci (Weinh). 2024; 11(40):e2401236.

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