电解
甲烷
催化作用
空位缺陷
电化学
法拉第效率
材料科学
化学工程
电极
无机化学
电流密度
电催化剂
化学
电解水
甲烷厌氧氧化
电流(流体)
可再生能源
膜
联轴节(管道)
作者
Qin Yang,Xiu Wang,Yuqi Yang,Ziyu Mi,Lei Wang,Yu‐Jhih Shen,Kang‐Shun Peng,Mingsheng Zhang,Tanmay Ghosh,Ruoou Yang,Linrong Huang,Jiguang Zhang,Zainul Aabdin,Wan Ru Leow,Sung‐Fu Hung,Ziyun Wang,Yanwei Lum
出处
期刊:Angewandte Chemie
[Wiley]
日期:2025-10-04
卷期号:64 (49): e202515396-e202515396
被引量:1
标识
DOI:10.1002/anie.202515396
摘要
Abstract CO 2 electrolysis to methane offers a promising route toward enabling long‐term storage of renewable energy. However, electrolysis in zero‐gap membrane electrode assembly (MEA) systems using conventional Cu‐based electrocatalysts is typically limited by relatively low methane productivity and Faradaic efficiency (FE). Here, we conceived an electrochemical assembly strategy that forms a Cu(111)‐dominant catalyst with vacancy defects. In an MEA system at a total current of 1.5 A, the catalyst (Def‐Cu 6 ) achieved a record methane FE of 71.46% and production rate of 0.28 µmol s −1 cm −2 , with relatively stable operation over 10 h. Density functional theory calculations reveal the crucial role of vacancy defects in a Cu(111) surface, which favors the hydrogenation of CO* and promotes methane formation over the competing CO* coupling pathway that leads to multicarbon products. Our findings demonstrate how vacancy defects can be tuned to control catalytic outcomes.
科研通智能强力驱动
Strongly Powered by AbleSci AI