电子转移
化学
双金属片
光催化
介孔材料
纳米反应器
催化作用
化学物理
联轴节(管道)
电子
介孔二氧化硅
纳米技术
动能
化学工程
人工光合作用
纳米颗粒
产量(工程)
曲率
电子供体
光化学
电子传输链
半导体
分支迁移
选择性
能量转换
作者
Junhua Zhang,Aixia Wang,Jinying Li,Ruohan Yu,Lina Yi,Zaiwang Zhao,Wei Zhang,Junhua Zhang,Risheng Bai,Dongyuan Zhao,Yuzhu Ma
摘要
The kinetic mismatch between the proton-coupled electron transfer pathway and the energy barrier of the C–C coupling severely restricts the selective photocatalytic CO2 reduction to high-value C2 products. Concave–convex curvature interface engineering offers a potent strategy to optimize asymmetric bimetallic sites and boost catalytic activity yet remains largely unexplored. Herein, we report a Ga atom-doped CuO photocatalyst with a sinusoidal nanocurvature interface, synthesized via a shear force-driven interface micellar coassembly strategy. 3D reconstruction of individual mesoporous nanoparticles presents a spindle-like structure and demonstrates a continuous “concave–convex–concave” sinusoidal nanocurvature interface. Bader charge analysis reveals that the sinusoidal interface induces the formation of an electron migration pathway, which reduces the electron migration resistance while increasing the number of transferred electrons. Experimental results and theoretical analyses demonstrate that the introduction of Ga atoms, which form asymmetric Ga–O–Cu sites, not only further reinforces the proton-coupled electron transfer pathway but also optimizes the local Cu coordination environment, stabilizes the key *CO and *CHO intermediates, and significantly lowers the energy barrier of the rate-determining step. The optimized catalyst achieves a C2H4 yield of 13.63 μmol g–1 h–1 with an electron-basis selectivity of up to 85.5%. This work opens a new horizon for engineering nanocurvature interfaces featuring asymmetric bimetallic sites, achieving selective transformation of CO2 to high-value C2 chemicals.
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