“Two Ships in a Bottle” Design for Zn–Ag–O Catalyst Enabling Selective and Long-Lasting CO2 Electroreduction

“Two Ships in a Bottle” Design for Zn–Ag–O Catalyst Enabling Selective and Long-Lasting CO2 Electroreduction

Electrochemical CO2 reduction (CO2RR) using renewable energy sources represents a sustainable means of producing carbon-neutral fuels. Unfortunately, low energy efficiency, poor product selectivity, and rapid deactivation are among the most intractable challenges of CO2RR electrocatalysts. Here, we...

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Veröffentlicht in:Journal of the American Chemical Society 2021-05, Vol.143 (18), p.6855-6864
Hauptverfasser: Zhang, Zhen, Wen, Guobin, Luo, Dan, Ren, Bohua, Zhu, Yanfei, Gao, Rui, Dou, Haozhen, Sun, Guiru, Feng, Ming, Bai, Zhengyu, Yu, Aiping, Chen, Zhongwei
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container_end_page 6864
container_issue 18
container_start_page 6855
container_title Journal of the American Chemical Society
container_volume 143
creator Zhang, Zhen
Wen, Guobin
Luo, Dan
Ren, Bohua
Zhu, Yanfei
Gao, Rui
Dou, Haozhen
Sun, Guiru
Feng, Ming
Bai, Zhengyu
Yu, Aiping
Chen, Zhongwei
description Electrochemical CO2 reduction (CO2RR) using renewable energy sources represents a sustainable means of producing carbon-neutral fuels. Unfortunately, low energy efficiency, poor product selectivity, and rapid deactivation are among the most intractable challenges of CO2RR electrocatalysts. Here, we strategically propose a “two ships in a bottle” design for ternary Zn–Ag–O catalysts, where ZnO and Ag phases are twinned to constitute an individual ultrafine nanoparticle impregnated inside nanopores of an ultrahigh-surface-area carbon matrix. Bimetallic electron configurations are modulated by constructing a Zn–Ag–O interface, where the electron density reconfiguration arising from electron delocalization enhances the stabilization of the *COOH intermediate favorable for CO production, while promoting CO selectivity and suppressing HCOOH generation by altering the rate-limiting step toward a high thermodynamic barrier for forming HCOO*. Moreover, the pore-constriction mechanism restricts the bimetallic particles to nanosized dimensions with abundant Zn–Ag–O heterointerfaces and exposed active sites, meanwhile prohibiting detachment and agglomeration of nanoparticles during CO2RR for enhanced stability. The designed catalysts realize 60.9% energy efficiency and 94.1 ± 4.0% Faradaic efficiency toward CO, together with a remarkable stability over 6 days. Beyond providing a high-performance CO2RR electrocatalyst, this work presents a promising catalyst-design strategy for efficient energy conversion.
doi_str_mv 10.1021/jacs.0c12418
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Moreover, the pore-constriction mechanism restricts the bimetallic particles to nanosized dimensions with abundant Zn–Ag–O heterointerfaces and exposed active sites, meanwhile prohibiting detachment and agglomeration of nanoparticles during CO2RR for enhanced stability. The designed catalysts realize 60.9% energy efficiency and 94.1 ± 4.0% Faradaic efficiency toward CO, together with a remarkable stability over 6 days. 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