催化作用
法拉第效率
化学
选择性
质子
电化学
联轴节(管道)
氢
氧化物
质子耦合电子转移
光化学
组合化学
同位素标记
无机化学
质子输运
氢键
协同催化
氧化还原
反应中间体
二氧化碳
可逆氢电极
多金属氧酸盐
化学渗透
钴
多相催化
化学工程
作者
Qi Jin,Ye Yang,Dongao Zhang,Xiaodong Yi,Guoxiong Wang,Zhou Chen
标识
DOI:10.1038/s41467-026-74410-4
摘要
Electrochemical CO2 reduction reaction in acidic media is fundamentally limited by competitive hydrogen evolution and poor selectivity toward multi-carbon products. Here we report a cooperative catalytic strategy that enables highly selective multi-carbon formation under strongly acidic conditions by regulating proton activation and interfacial solvation. By exploiting the copper oxide nanosheets and integrating an immobilized cobalt tetra(4-carboxyphenyl)porphyrin, a dual-functional interface is constructed that steers abundant protons toward productive C–C bond formation. This synergy sustains C-C coupling at high current densities and suppresses parasitic hydrogen evolution. As a result, the hybrid catalyst delivers a multi-carbon Faradaic efficiency of up to 89.5% with partial current densities exceeding 1 A cm−2 in pH 2 ± 0.1 electrolyte, and maintains high selectivity even at pH 0.7 ± 0.05. Operando spectroscopic analyses and theoretical calculations reveal that regulated proton activation enables efficient formation of key C-C coupling intermediates and stabilizes the catalytic interface under acidic conditions. These results demonstrate a viable route to achieve efficient CO2 electroreduction to multi-carbon products in acidic environments through molecular control of proton utilization. Efficient carbon dioxide reduction to multi-carbon products in acidic media is hindered by competing hydrogen evolution. Here, the authors report a hybrid catalyst that regulates proton transfer to drive highly selective multi-carbon formation at high current densities.
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