析氧
格式化
法拉第效率
制氢
催化作用
材料科学
化学工程
电解
氧气
生物量(生态学)
氢
分解水
反应机理
可逆氢电极
钴
无机化学
化学
反应中间体
电解水
电化学
纳米技术
作者
Jianyun Gan,Yi Yang,Yang Wu,Linxin Zhong,Yunpeng Liu,Zhongxin Chen,Kasim Ocakoglu,Emmanuel I. Iwuoha,Bin Liu,Xinwen Peng
摘要
ABSTRACT Cobalt oxyhydroxide (CoOOH) is a promising catalyst for biomass electrooxidation, yet its reaction mechanism remains contentious regarding its competition with the oxygen evolution reaction (OER) at high overpotentials. Herein, we resolve this controversy by identifying a key intermediate that triggers a switch from the lattice oxygen mechanism (LOM) for OER to a concerted proton–electron transfer (CPET) mechanism for the glucose oxidation reaction (GOR). Operando spectroscopy and isotope‐labeling experiments reveal that the electrochemically generated O–Co 4+ (O * )–O site preferentially extracts protons from glucose via CPET, which effectively suppresses O─O coupling and parasitic oxygen evolution. This mechanism enables CoOOH to achieve a high GOR current density of 100 mA cm − 2 at only 1.23 V vs. RHE with a formate Faradaic efficiency of 97.0%. Moreover, the two‐electrode flow electrolyzer integrating GOR with hydrogen evolution reaction achieves a current of 2.7 A (300 mA cm −2 ) at a low cell voltage of 1.70 V, co‐producing formate and hydrogen with high Faradaic efficiencies (87.5% and 98.4%, respectively), and maintaining stable operation for over 100 h. This work not only clarifies the CPET‐dominated mechanism in biomass electrooxidation but also proposes a scalable strategy for energy‑saving coproduction of valuable chemicals and green hydrogen.
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