催化作用
吸附
选择性
离解(化学)
电解质
化学
路易斯酸
无机化学
法拉第效率
铜
表面工程
化学工程
膜
氢
电极
电催化剂
乙烯
活动站点
多相催化
铬
联轴节(管道)
乙二醇
电化学
可逆氢电极
纳米技术
电解水
选择性吸附
材料科学
作者
Changze Wei,Zheng Lin,Guokang Han,Zhengyi Qian,Yuan Zhao,Fei Liu,Yingjun Tan,Na Ye,Yi Wei,Chenhui Zhou,C G Sun,Mingchuan Luo,Shaojun Guo
出处
期刊:Nano Letters
[American Chemical Society]
日期:2026-02-15
卷期号:26 (7): 2726-2734
标识
DOI:10.1021/acs.nanolett.5c06301
摘要
Copper-based electrocatalysts have shown great potential for electrolytic CO2 reduction (CO2RR) to value-added multi-carbon products but suffer from poor selectivity and activity due to the uncontrollable CO adsorption and sluggish C-C coupling kinetics. Herein, we develop a dopant-driven interfacial engineering strategy by incorporating chromium (Cr) into copper oxide, which in situ reconstructs to Cu-CrOx heterointerfaces under CO2RR conditions. Combined experimental and theoretical analyses reveal that Lewis acidic CrOx clusters tailor the electronic structure of Cu sites, thereby strengthening the CO adsorption and accelerating C-C coupling. The Cu-CrOx interface also promotes water dissociation to supply active hydrogen species for multiple hydrogenation steps. The optimized catalyst achieves a 59.2% faradaic efficiency for ethylene and maintains stable operation for over 110 h at 2.45 V in a membrane electrode assembly electrolyzer. This work highlights dopant-enabled interfacial engineering as a versatile strategy for steering CO2RR activity and selectivity toward multi-carbon products, offering mechanistic insights that advance the field.
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