Intercalated Iridium Diselenide Electrocatalysts for Efficient pH‐Universal Water Splitting

Developing bifunctional catalysts for both hydrogen and oxygen evolution reactions is a promising approach to the practical implementation of electrocatalytic water splitting. However, most of the reported bifunctional catalysts are only applicable to alkaline electrolyzer, although a few are effect...

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Veröffentlicht in:	Angewandte Chemie International Edition 2019-10, Vol.58 (41), p.14764-14769
Hauptverfasser:	Zheng, Tingting, Shang, Chunyan, He, Zhihai, Wang, Xinyi, Cao, Cong, Li, Hongliang, Si, Rui, Pan, Bicai, Zhou, Shiming, Zeng, Jie
Format:	Artikel
Sprache:	eng
Schlagworte:	Catalysis Catalysts electrocatalysis Electrocatalysts Industrial applications Iridium iridium diselenide Lithium lithium intercalation overall water splitting Oxygen Oxygen evolution reactions pH effects Splitting Water splitting
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creator	Zheng, Tingting Shang, Chunyan He, Zhihai Wang, Xinyi Cao, Cong Li, Hongliang Si, Rui Pan, Bicai Zhou, Shiming Zeng, Jie
description	Developing bifunctional catalysts for both hydrogen and oxygen evolution reactions is a promising approach to the practical implementation of electrocatalytic water splitting. However, most of the reported bifunctional catalysts are only applicable to alkaline electrolyzer, although a few are effective in acidic or neutral media that appeals more to industrial applications. Here, a lithium‐intercalated iridium diselenide (Li‐IrSe2) is developed that outperformed other reported catalysts toward overall water splitting in both acidic and neutral environments. Li intercalation activated the inert pristine IrSe2 via bringing high porosities and abundant Se vacancies for efficient hydrogen and oxygen evolution reactions. When Li‐IrSe2 was assembled into two‐electrode electrolyzers for overall water splitting, the cell voltages at 10 mA cm−2 were 1.44 and 1.50 V under pH 0 and 7, respectively, being record‐low values in both conditions. Lithium‐intercalated iridium diselenide (Li‐IrSe2) is presented, outperforming other reported catalysts toward overall water splitting in both acidic and neutral environments. Li intercalation activated the inert pristine IrSe2 by bringing about high porosities and abundant Se vacancies for efficient hydrogen and oxygen evolution reactions.
doi_str_mv	10.1002/anie.201909369
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subjects	Catalysis Catalysts electrocatalysis Electrocatalysts Industrial applications Iridium iridium diselenide Lithium lithium intercalation overall water splitting Oxygen Oxygen evolution reactions pH effects Splitting Water splitting
title	Intercalated Iridium Diselenide Electrocatalysts for Efficient pH‐Universal Water Splitting
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