塔菲尔方程
析氧
催化作用
兴奋剂
材料科学
氧化物
电化学
异质结
交换电流密度
密度泛函理论
分解水
结构稳定性
化学工程
氧气
纳米技术
化学
无机化学
氧化还原
化学物理
电催化剂
掺杂剂
作者
Md. Mofakkharulhashan,Shiqi Wang,Hugo L. S. Santos,Mykhailo Chundak,Mikko Ritala,Pedro H. C. Camargo
出处
期刊:Small science
[Wiley]
日期:2025-12-24
卷期号:6 (2): e202500546-e202500546
被引量:1
标识
DOI:10.1002/smsc.202500546
摘要
The oxygen evolution reaction (OER) is the primary kinetic bottleneck in water electrolysis, requiring catalysts that are both efficient and durable. Here, a MnCoNi–RuO 2 (MCN–RuO 2 ) heterostructured catalyst synthesized via a controlled impregnation–annealing–etching process that integrates multimetal doping with mixed‐phase oxide formation is reported. Structural analyses reveal a RuO 2 host lattice interfaced with MnO and spinel‐type CoNiO x domains, generating lattice distortion, oxygen vacancies, and defect‐rich interfaces that tune the electronic structure and enrich active sites. Electrochemical tests demonstrate overpotentials as low as 200 mV at 10 mA cm −2 , a low Tafel slope, and markedly improved stability relative to commercial RuO 2 and IrO 2 . The catalyst also retains high activity under acidic conditions and, when implemented in an anion exchange membrane water electrolyzer, sustains industrially relevant operation for 100 h with minimal degradation. Density functional theory calculations reveal that multimetal incorporation drives charge redistribution, lowers the work function, and shifts Ru‐4d states, reducing the barrier for the rate‐determining *O → *OOH step while enhancing stability against Ru dissolution. These findings establish MCN–RuO 2 as a versatile, Ir‐free platform and demonstrate multimetal doping with heterointerface engineering as a powerful strategy for designing next‐generation OER catalysts.
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