Blending Cr2O3 into a NiO-Ni Electrocatalyst for Sustained Water Splitting

The rising H2 economy demands active and durable electrocatalysts based on low‐cost, earth‐abundant materials for water electrolysis/photolysis. Here we report nanoscale Ni metal cores over‐coated by a Cr2O3‐blended NiO layer synthesized on metallic foam substrates. The Ni@NiO/Cr2O3 triphase materia...

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Bibliographic Details
Published in:Angewandte Chemie 2015-10, Vol.127 (41), p.12157-12161
Main Authors: Gong, Ming, Zhou, Wu, Kenney, Michael James, Kapusta, Rich, Cowley, Sam, Wu, Yingpeng, Lu, Bingan, Lin, Meng-Chang, Wang, Di-Yan, Yang, Jiang, Hwang, Bing-Joe, Dai, Hongjie
Format: Article
Language:English
Subjects:
Chemistry
Chromoxid
Elektrokatalysatoren
Nachhaltige Chemie
Wasserspaltung
Wasserstoffentwicklung
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Summary:The rising H2 economy demands active and durable electrocatalysts based on low‐cost, earth‐abundant materials for water electrolysis/photolysis. Here we report nanoscale Ni metal cores over‐coated by a Cr2O3‐blended NiO layer synthesized on metallic foam substrates. The Ni@NiO/Cr2O3 triphase material exhibits superior activity and stability similar to Pt for the hydrogen‐evolution reaction in basic solutions. The chemically stable Cr2O3 is crucial for preventing oxidation of the Ni core, maintaining abundant NiO/Ni interfaces as catalytically active sites in the heterostructure and thus imparting high stability to the hydrogen‐evolution catalyst. The highly active and stable electrocatalyst enables an alkaline electrolyzer operating at 20 mA cm−2 at a voltage lower than 1.5 V, lasting longer than 3 weeks without decay. The non‐precious metal catalysts afford a high efficiency of about 15 % for light‐driven water splitting using GaAs solar cells. Ein dreiphasiger Elektrokatalysator aus einem Nickelkern mit einer Cr2O3‐vermischten NiO‐Schicht (CrNN) auf Metallschaumsubstrat zeigt hervorragende Aktivität und Stabilität in der Wasserstoffentwicklung in basischer Lösung. Der CrNN‐Katalysator ermöglichte eine kontinuierliche Wasserelektrolyse über mehr als 500 Stunden bei einer Spannung von unter 1.5 V.
ISSN:0044-8249
1521-3757
DOI:10.1002/ange.201504815