催化作用
化学
星团(航天器)
密度泛函理论
非共价相互作用
铜
选择性
合理设计
卡宾
法拉第效率
组合化学
分子
甲烷
纳米技术
活动站点
光谱学
金属
钥匙(锁)
计算化学
含时密度泛函理论
选择性催化还原
立体化学
还原(数学)
配体(生物化学)
功能理论
作者
J C Zhang,Kai Hua,Lijuan Gong,Z Chen,Li‐Ying Sun,Guo‐Ping Yang,Ying‐Feng Han
摘要
ABSTRACT Copper‐based catalysts are promising for CO 2 reduction to hydrocarbons; however, selective CH 4 generation remains challenging because of the presence of competing pathways and an insufficient understanding of active site control. Herein, we develop a ligand‐microengineering strategy to synthesize a series of fully N‐heterocyclic carbene (NHC)‐protected Cu 4 O clusters, [Cu 4 ( μ 4 ‐O)] L 2 (PF 6 ) 2 ( L = 1a–1d , denoted as 2a–2d ), via a green and efficient ball‐milling approach. Of the four evaluated preparations, cluster 2c exhibits the optimal CH 4 Faradaic efficiency (), with a value of 67.5% ± 2.1% at –1.4 V versus RHE. Integrated in situ spectroscopy and density functional theory (DFT) calculations reveal that unique secondary‐sphere noncovalent interactions (hydrogen‐bonding and C–H···π) present in 2c provide additional stabilization for the key *CHO intermediate, maximizing CH 4 selectivity. This study not only demonstrates the unique advantages of NHC ligands in constructing stable and efficient copper cluster catalysts but also establishes a new paradigm for precisely steering CO 2 electroreduction selectivity through the rational design of noncovalent interactions within the secondary coordination sphere.
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