Cu2O nanostructures and enhanced catalytic performance in electrochemical reduction of CO2 被引量：4

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摘要 Novel,hierarchical,flower-like Ag/Cu2O and Au/Cu2O nanostructures were successfully fabricated and applied as efficient electrocatalysts for the electrochemical reduction of CO2.Cu2O nanospheres with a uniform size of^180 nm were initially synthesized.Thereafter,Cu2O was used as a sacrificial template to prepare a series of Ag/Cu2O composites through galvanic replacement.By varying the Ag/Cu atomic ratio,Ago.12/Cu2O,having a hierarchical,flower-like nanostructure with intersecting Ag nanoflakes encompassing an inner Cu2O sphere,was prepared.The as-prepared Ag/Cu2O samples presented higher Faradaic efficiencies(FE)for CO and relatively suppressed H2 evolution than the parent Cu2O nanospheres due to the combination of Ag with Cu2O in the former.Notably,the highest CO evolution rate was achieved with Ago.12/Cu2O due to the larger electroactive surface area furnished by the hierarchical structure.The same hier-archical flower-like structure was also obtained for the Auo./Cu2O composite,where the FEco(10%)was even higher than that of Ago.12/Cu2O.Importantly,the results reveal that Ago.12/Cu2O and Auo./Cu2O both exhibit remarkably improved stability relative to Cu2O.This study presents a facile method of developing hierarchical metal-oxide composites as fficient and stable electrocatalysts for the electrochemical reduction of CO2.

作者 Mengyun Wang Shengbo Zhang Mei Li Aiguo Han Xinli Zhu Qingfeng Ge Jinyu Han Hua Wang

机构地区 Collaborative Innovation Center of Chemical Science and Engineering Department of Chemistry and Biochemistry

出处《Frontiers of Chemical Science and Engineering》 SCIE EI CAS CSCD 2020年第5期813-823,共11页 化学科学与工程前沿（英文版）

基金 We are grateful to the Analysis and Test Center of Tianjin University for providing XRD,SEM,and TEM characterization.We also acknowledge the National Natural Science Foundation of China(Grant Nos.21576204 and 21206117)for financial support.

关键词 bimetallic nanostructure hierarchical metal/oxide nanomaterial galvanic replacement electrochemical reduction of CO2

分类号 O643.3 [理学—物理化学] TB383 [一般工业技术—材料科学与工程]

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