制氢
催化作用
甲醇
法拉第效率
析氧
无机化学
可逆氢电极
材料科学
氢氧化物
电解
氢
电解水
格式化
氧气
化学工程
化学
碱性水电解
密度泛函理论
电化学
钴
电催化剂
拉曼光谱
氢氧化钴
电极
甲醇燃料
氢燃料
双金属
作者
Jing Du,Xiongbiao Xue,Shuyuan Yang,Wei Lichan,Shirui Cui,Xiaolu Feng,Junjie Wang,Zelong Li
摘要
ABSTRACT Electrocatalytic methanol oxidation reaction (MOR) coupled with hydrogen evolution (HER) can lower the energy cost of H 2 production while valorizing methanol to formate. Developing efficient, low‐cost MOR catalysts for alkaline media remains challenging. Here, we report nickel–cobalt bimetal hydroxide (NiCoO x H y ) nanosheets as a highly active and durable MOR catalysts. The optimized NiCoO x H y requires only 1.40 V versus the reversible hydrogen electrode (RHE) to deliver a current density of 400 mA cm −2 and achieves >99% Faradaic efficiency toward formate at 1.45 V, representing one of the most efficient MOR electrocatalysts reported. In a two‐electrode system, methanol oxidation coupled with HER lowers the cell voltage by ∼310 mV compared to conventional water electrolysis at 300 mA cm −2 . In situ Raman and x‐ray absorption spectroscopy, together with isotope‐labeling studies, reveal that cobalt incorporation promotes the formation of high‐valence M 4+ species, which activate lattice oxygen and accelerate methanol electrooxidation. Density functional theory (DFT) calculations confirm that highly oxidized M 4+ species enhance metal–oxygen orbital hybridization, activating lattice oxygen and reducing reaction barriers. This work highlights lattice oxygen engineering via electronic structure modulation as an effective strategy for designing advanced electrocatalysts toward sustainable hydrogen‐formate co‐production.
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