Modulating metal-organic frameworks for catalyzing acidic oxygen evolution for proton exchangemembrane water electrolysis 被引量：5

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摘要 Proton exchangemembrane(PEM)water electrolysis represents one of the most promising technologies to achieve green hydrogen production,but currently its practical viability is largely affected by the slow reaction kinetics of the anodic oxygen evolution reaction(OER)in an acidic environment.While noble metal-based catalysts containing iridium or ruthenium are excellent catalysts for the acidic OER,their practical use in PEM electrolyzers is hindered due to their low abundance and high cost.Most recently,metal-organic frameworks(MOFs)have been demonstrated as a perfect platform to facilitate the design of acidic OER catalysts with both high efficiency and cost-effectiveness.Here,we pro-vide a timely and comprehensive overview of the recent progress on MOF-based acidic OER catalysts.The fundamental mechanisms of the acidic OER are first introduced,followed by a summary of the development of pristine MOFs and MOF derivatives as acidic OER catalysts.Importantly,a number of catalyst design strategies are discussed aiming at improving the acidic OER catalytic per-formance of MOF-based candidates.The integration of MOF-based catalysts into real PEM water electrolyzers is also included.Finally,future research directions are provided to achieve better MOF-based catalysts operational in acidic envi-ronments and PEM devices.

作者 Xiaomin Xu Hainan Sun San Ping Jiang Zongping Shao

机构地区 WA School of Mines:Minerals Department of Materials Science and Engineering State Key Laboratory of Materials-Oriented Chemical Engineering

出处《SusMat》 2021年第4期460-481,共22页 可持续发展材料（英文）

基金 This work was supported by the Australian Research Council Discovery Projects(Grant Nos.ARC DP200103332 and ARC DP200103315).

关键词 acidic water oxidation ELECTROCATALYSIS hydrogen production metal-organic frameworks oxy-gen evolution reaction proton exchange membrane water electrolysis

分类号 O64 [理学—物理化学]

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