化学
拉曼光谱
选择性
密度泛函理论
氧化物
吸收(声学)
多孔性
环氧乙烷
化学工程
无机化学
铜
乙烯
吸收光谱法
碳纤维
X射线吸收光谱法
电流密度
基质(化学分析)
导电体
催化作用
分析化学(期刊)
光谱学
作者
Yuning Lou,Yuejiang Han,Yuxuan Zhang,Lin Liu,Zheng‐Bo Han
摘要
Although Cu 2 O(111) is thermodynamically favorable for CO 2 electroreduction, ethylene production is limited by insufficient Cu + stabilization, leading to modest selectivity and durability. Herein, we report an interfacial engineering strategy to construct nanoscale-coupled Cu 2 O–ZrO 2 heterointerfaces that stabilize Cu + and promote C–C coupling. Using a zirconium-based metal-organic framework as a confined-conversion template, uniformly dispersed Cu 2 O(111)–ZrO 2 interfaces are generated within a conductive porous carbon matrix (CuZr@C). CuZr@C delivers FE C2H4 = 72.1% at j C2H4 = 39.0 mA cm –2 (−1.3 V vs RHE) in an H cell with >70% retention after 120 h and j C2H4 = 101.6 mA cm –2 in a flow cell. Operando X-ray absorption spectroscopy and Raman confirm Cu + stabilization and high local CO coverage at the heterointerface. Density functional theory reveals a reduced free-energy barrier of 0.68 eV for the rate-determining *OCCO → *OCCHO step, establishing Cu 2 O(111)-based oxide heterointerfaces as effective platforms for durable and selective CO 2 RR to multicarbon products.
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