催化作用
选择性
密度泛函理论
价(化学)
铜
氧气
键裂
化学
一氧化碳
材料科学
合理设计
氧化态
组合化学
多相催化
反应机理
曲面重建
工作(物理)
化学工程
纳米技术
分子
原位
光化学
电子结构
反应中间体
曲面(拓扑)
氧化还原
化学物理
科技与社会
光谱学
作者
Jie Li,Yang Chen,Lulu Chen,Yong Zhang,Rui Xiong,Li Tan,Xianzhi Fu,Sen Lin
摘要
ABSTRACT The pursuit of precise product control in CO 2 hydrogenation represents a central challenge in catalysis, where the inherent complexity of reaction networks often obscures the fundamental connection between surface structure and catalytic selectivity. Here, by integrating density functional theory and microkinetic modeling, we systematically decouple the distinct roles of surface oxygen termination and Cu coordination geometry in regulating catalytic selectivity of Mo 2 CO x catalysts. We identify three structurally sensitive regimes: pristine Mo 2 CO x surfaces facilitate efficient C═O bond cleavage to form CO and CH 4 , with higher oxygen coverage enhancing CO selectivity and promoting CH 3 OH among hydrogenated products; Cu‐adsorbed Mo 2 CO x enhances CH 4 generation by maintaining C═O scission while suppressing CO desorption; and Cu‐doped Mo 2 CO x promotes CH 3 OH formation by reducing surface oxophilicity and stabilizing key oxygenated intermediates. Crucially, we establish the Cu oxidation state as a quantitative descriptor for CH 3 OH/CH 4 selectivity, with a higher valence favoring CH 3 OH production. These mechanistic insights, corroborated by in situ spectroscopy and catalytic tests, bridge structure sensitivity with macroscopic performance. This work establishes general design principles for selective CO 2 conversion on MXene‐based catalysts, providing a foundation for the rational design of advanced CO 2 hydrogenation systems.
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