催化作用
选择性
乙醇
乙烯
化学
电化学
法拉第效率
拉曼光谱
电子效应
不对称氢化
乙醇燃料
组合化学
电催化剂
钯
多相催化
有机化学
原位
平衡(能力)
表面工程
还原(数学)
光谱学
循环伏安法
作者
Zihong Wang,Jiasen Guo,Dazhuang Wang,Jun Ma,Xuefei Feng,Zhuangzhuang Cui,Digen Ruan,Xuan Luo,Jiajia Fan,Jiacheng Yang,Bing‐Qing Xiong,Xiaodi Ren
标识
DOI:10.1002/anie.202523475
摘要
ABSTRACT Electrochemical CO 2 reduction to ethanol faces a fundamental challenge: competing ethylene formation through shared C 2 intermediates. While previous studies focused on modifying catalyst electronic structures or increasing *CO coverage, the critical role of competitive hydrogenation pathways remains unexplored. Here, we demonstrate that the selectivity between ethanol and ethylene is governed by the balance between Langmuir–Hinshelwood (surface *H) and Eley–Rideal (solvent H) hydrogenation mechanisms. Through hierarchically assembled BPEI/PT interfaces, we dynamically modulate this balance by reconstructing interfacial hydrogen‐bond networks without altering catalyst electronic properties. In situ Raman spectroscopy captures enhanced *OCHCH 2 /*OCHCH 3 intermediates, directly correlating ethanol selectivity with suppressed ER pathway. Combined experimental and theoretical studies establish quantitative relationships between hydrogen‐bond strength and pathway selectivity. This strategy achieves 38.7% ethanol Faradaic efficiency (FE) at 900 mA cm − 2 on CuO‐derived catalysts (116% improvement) and 53% at 800 mA cm − 2 on CuAg systems—among the highest reported efficiencies. Our findings reveal that controlling competitive hydrogenation pathways through interfacial engineering provides an independent parameter for steering CO 2 reduction selectivity.
科研通智能强力驱动
Strongly Powered by AbleSci AI