| Literature DB >> 33009695 |
Likun Xiong1,2, Xiang Zhang1,2, Hao Yuan3, Juan Wang4, Xuzhou Yuan1,2, Yuebin Lian1,2, Huidong Jin1,2, Hao Sun1,2, Zhao Deng1,2, Dan Wang1,2, Jiapeng Hu1,2, Huimin Hu1,2, Jinho Choi1,2, Jiong Li4, Yufeng Chen3, Jun Zhong3, Jun Guo5, Mark H Rümmerli1,2, Lai Xu3, Yang Peng1,2.
Abstract
Electrocatalytic conversion of carbon dioxide into high-value multicarbon (C2+ ) chemical feedstocks offers a promising avenue to liberate the chemical industry from fossil-resource dependence and eventually close the anthropogenic carbon cycle but is severely impeded by the lack of high-performance catalysts. To break the linear scaling relationship of intermediate binding and minimize the kinetic barrier of CO2 reduction reactions, ternary Cu-Au/Ag nanoframes were fabricated to decouple the functions of CO generation and C-C coupling, whereby the former is promoted by the alloyed Ag/Au substrate and the latter is facilitated by the highly strained and positively charged Cu domains. Thus, C2 H4 production in an H-cell and a flow cell occurred with high Faradic efficiencies of 69±5 and 77±2 %, respectively, as well as good electrocatalytic stability and material durability. In situ IR and DFT calculations unveiled two competing pathways for C2 H4 generation, of which direct CO dimerization is energetically favored.Entities:
Keywords: carbon dioxide; electroreduction; heterogeneous catalysis; linear scaling relationships; metal nanoframes
Year: 2020 PMID: 33009695 DOI: 10.1002/anie.202012631
Source DB: PubMed Journal: Angew Chem Int Ed Engl ISSN: 1433-7851 Impact factor: 15.336