面(心理学)
催化作用
联轴节(管道)
材料科学
产量(工程)
化学物理
工作(物理)
曲面重建
曲面(拓扑)
纳米技术
化学稳定性
理论(学习稳定性)
金属
活动站点
过渡金属
刻面
化学
电催化剂
化学工程
多相催化
结晶学
热稳定性
氧化还原
析氧
作者
Ze Wu,Xiaorong Zhu,Xupeng Qin,Chu Zhang,Nannan Guo,D C Chen,Dafeng Yan,Yue Wang,Ruping Miao,Kefan Zhang,Qinghua Liu,Chade Lv,L C WANG,S Y Wang,Chen Chen
摘要
ABSTRACT Electrocatalytic C–N coupling represents a green synthesis platform, yet the dynamic evolution of catalyst surfaces during the reaction remains poorly understood. Here, we report a nitrate‐dominated, preferential facet evolution on Cu single crystals that directs less active (110) and (100) facets toward the highly active (111) configuration. The Cu(111) surface delivers a urea yield of 5.2 mg h −1 cm −2 from CO 2 and NO 3 − , outperforming (110) and (100) by about 4‐ and 26‐fold, respectively, while maintaining excellent stability. Experimental and theoretical analyses reveal that this facet reconstruction is associated with spontaneous chemical interaction between nitrate and metallic copper, alongside the thermodynamic stability of the Cu(111) facet. Significantly, the pristine Cu(111) surface consistently outperforms Cu(110) and Cu(100), highlighting its intrinsic catalytic superiority. This work provides insights into nitrate‐dominated C–N coupling, advancing the design of dynamically active electrocatalysts.
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