材料科学
纳米团簇
铜
电合成
催化作用
法拉第效率
电化学
硫酚
电催化剂
配体(生物化学)
纳米技术
氧化还原
选择性
化学工程
无机化学
活动站点
金属
合理设计
组合化学
表面工程
纳米颗粒
作者
W. Zhang,Guangfang Li,C. Wang,Lin Wang,Ruohan Yu,Wei Du,Chengxin Zhu,Ling Peng,Yongshuang Xi,Hui Li Wang,Ying Yu,Rong Chen
标识
DOI:10.1002/adfm.202530964
摘要
ABSTRACT Ligand‐modified electrocatalysts enable control of surface structure and active site environments, elevated selectivity in electrochemical CO 2 reduction. However, challenges arise that ligand coverage often blocks catalytic sites and reduces metallic conductivity, hindering the application of this strategy at high current densities. Here, by engineering a high‐density array of fluorinated aryl thiol ligand (SPhF 2 )‐protected copper nanoclusters on two‐dimensional copper nanosheets, we demonstrate the development of stable, efficient, and selective Cu electrocatalysts for CO 2 reduction into C 2 products. This design constructs a high concentration of accessible active sites while preserving conductivity through the underlying nanosheet, achieving a C 2 Faradaic efficiency of 95.6 % with a partial current density of −673.1 mA cm −2 . By integrating in situ spectroscopy with multiscale simulations, we reveal that the thiophenol anchors build a hydrophobic microenvironment while electronically tuning the copper active sites. This dual‐functionality stabilizes the crucial * CO intermediate coverage and significantly lowers the kinetic barrier for * CO dimerization, thus favoring the C−C coupling pathway. This strategy of designing ligand‐bridged cluster/support interfaces paves the way for overcoming the selectivity‐activity trade‐off in complex electrocatalytic reactions.
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