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Self-Catalyzed Ru Redeposition Based on Co, Zn-Driven Double Anchoring for Robust Acidic Water Oxidation

Yanan Zhou, Ruo‐Yao Fan, Yusheng Zhang, Ning Yu, Han Hu, Mirabbos Hojamberdiev, Bin Dong, Yong‐Ming Chai

2024ACS Energy Letters14 citationsDOI

Abstract

The redeposition of high-valence Ru n >4+ at oxidation potential is slower than its dissolution due to weak electronic interactions with substrates, limiting water oxidation performance. We propose a novel self-catalyzed redeposition strategy fuelled by Co and Zn codoping to establish a new dissolution–redeposition balance of Ru. Co, Zn-doped RuO 2 with unique double anchoring effect is prepared, where electron-donating Co and Zn reduce Ru n >4+ leaching by inhibiting overoxidation and shortening Ru–O bonds (first anchoring). More importantly, Ru n >4+ is rapidly and stably deposited as active Ru(OH) 6 2– through Co 2+ /Co 3+ redox-driven self-catalysis (second anchoring). Regulating the Co content can modulate the self-catalysis strength, thus stabilizing dissolution–redeposition equilibrium via directional electron flow from Co to Ru. The redeposited Co 0.2 Zn 0.8 @RuO 2 presents shortened Ru–O bonds and abundant defects, displaying ultralow overpotential at 10 mA·cm –2 (150 mV), surpassing the RuO 2 benchmark and most catalysts. Furthermore, Co 0.2 Zn 0.8 @RuO 2 exhibits excellent stability at 500 mA·cm –2 for 100 h. This self-catalyzed redeposition offers a new routine to break the activity–stability trade-off of electrocatalysts, especially in membrane water electrolyzers.

Topics & Concepts

AnchoringCatalysisChemistryInorganic chemistryRutheniumMaterials scienceOrganic chemistryStructural engineeringEngineeringElectrocatalysts for Energy ConversionElectrochemical Analysis and ApplicationsCatalytic Processes in Materials Science