Recent Advances on Water‐Splitting Electrocatalysis Mediated by Noble‐Metal‐Based Nanostructured Materials

Electrochemical water splitting plays a crucial role in the development of clean and renewable energy production and conversion, which is a promising pathway to reduce social dependence on fossil fuels. Thus, highly active, cost‐efficient, and robust catalysts must be developed to reduce the reactio...

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Veröffentlicht in:Advanced energy materials 2020-03, Vol.10 (11), p.n/a
Hauptverfasser: Li, Yingjie, Sun, Yingjun, Qin, Yingnan, Zhang, Weiyu, Wang, Lei, Luo, Mingchuan, Yang, Huai, Guo, Shaojun
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Sprache:eng
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Zusammenfassung:Electrochemical water splitting plays a crucial role in the development of clean and renewable energy production and conversion, which is a promising pathway to reduce social dependence on fossil fuels. Thus, highly active, cost‐efficient, and robust catalysts must be developed to reduce the reaction overpotential and increase electrocatalytic efficiency. In this review, recent research efforts toward developing advanced electrocatalysts based on noble metals with outstanding performance for water splitting catalysis, which is mainly dependent on their structure engineering, are summarized. First, a simple description of the water‐splitting mechanism and some promising structure engineering strategies are given, including heteroatom incorporation, strain engineering, interface/hybrid engineering, and single atomic construction. Then, the underlying relationship between noble metal electronic/geometric structure and performance for water splitting is discussed with the assistance of theoretical simulation. Finally, a personal perspective is provided in order to highlight the challenges and opportunities for developing novel electrocatalysts suitable for a wide range of commercial uses in water splitting for structural engineering applications. Structure engineering offers great opportunities for nanostructured catalysts to improve the electrocatalytic performance of water splitting. Some strategies, including heteroatom incorporation, strain engineering, interface/hybrid engineering, and single atomic construction, can tailor the electronic structure and geometrical construction, further tuning the chemical properties of catalysts to promote electrochemical water splitting.
ISSN:1614-6832
1614-6840
DOI:10.1002/aenm.201903120