气凝胶
石墨烯
催化作用
材料科学
星团(航天器)
瞬态(计算机编程)
化学工程
纳米技术
化学
计算机科学
有机化学
操作系统
工程类
程序设计语言
作者
Kaiyuan Liu,H. F. Shen,Zhiyi Sun,Qiang Zhou,Guoqiang Liu,Zhongti Sun,Wenxing Chen,Xin Gao,Pengwan Chen
标识
DOI:10.1038/s41467-025-56534-1
摘要
Designing asymmetrical structures is an effective strategy to optimize metallic catalysts for electrochemical carbon dioxide reduction reactions. Herein, we demonstrate a transient pulsed discharge method for instantaneously constructing graphene-aerogel supports asymmetric copper nanocluster catalysts. This process induces the convergence of copper atoms decomposed by copper chloride onto graphene originating from the intense current pulse and high temperature. The catalysts exhibit asymmetrical atomic and electronic structures due to lattice distortion and oxygen doping of copper clusters. In carbon dioxide reduction reaction, the selectivity and activity for ethanol production are enhanced by the asymmetric structure and abundance of active sites on catalysts, achieving a Faradaic efficiency of 75.3% for ethanol and 90.5% for multicarbon products at −1.1 V vs. reversible hydrogen electrode. Moreover, the strong interactions between copper nanoclusters and graphene-aerogel support confer notable long-term stability. We elucidate the key reaction intermediates and mechanisms on Cu4O-Cu/C2O1 moieties through in situ testing and density functional theory calculations. This study provides an innovative approach to balancing activity and stability in asymmetric-structure catalysts for energy conversion. Asymmetric catalysts show promise for CO2 electrochemical catalytic reduction. Here, the authors develop a pulsed discharge method to prepare graphene-aerogel-supported asymmetric Cu nanoclusters catalysts that enhance electrochemical CO2 conversion into multicarbon products.
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