Copper adparticle enabled selective electrosynthesis of n-propanol

Jun Li; Fanglin Che; Yuanjie Pang; Chengqin Zou; Jane Y. Howe; Thomas Burdyny; Jonathan P. Edwards; Yuhang Wang; Fengwang Li; Ziyun Wang; Phil De Luna; Cao‐Thang Dinh; Tao‐Tao Zhuang; Makhsud I. Saidaminov; Shaobo Cheng; Tianpin Wu; Y. Zou Finfrock; Lu Ma; Shang‐Hsien Hsieh; Yi‐Sheng Liu; Gianluigi A. Botton; W. F. Pong; Xi‐Wen Du; Jinghua Guo; Tsun‐Kong Sham; Edward H. Sargent; David Sinton

doi:10.1038/s41467-018-07032-0

Copper adparticle enabled selective electrosynthesis of n-propanol

Jun Li(University of Toronto), Fanglin Che(University of Toronto), Yuanjie Pang(University of Toronto), Chengqin Zou(Tianjin University), Jane Y. Howe(Hitachi Global Storage Technologies (United States)), Thomas Burdyny(University of Toronto), Jonathan P. Edwards(University of Toronto), Yuhang Wang(University of Toronto), Fengwang Li(University of Toronto), Ziyun Wang(University of Toronto), Phil De Luna(University of Toronto), Cao‐Thang Dinh(University of Toronto), Tao‐Tao Zhuang(University of Toronto), Makhsud I. Saidaminov(University of Toronto), Shaobo Cheng(McMaster University), Tianpin Wu(Argonne National Laboratory), Y. Zou Finfrock(Argonne National Laboratory), Lu Ma(Argonne National Laboratory), Shang‐Hsien Hsieh(Tamkang University), Yi‐Sheng Liu(Lawrence Berkeley National Laboratory), Gianluigi A. Botton(McMaster University), W. F. Pong(Tamkang University), Xi‐Wen Du(Tianjin University), Jinghua Guo(Lawrence Berkeley National Laboratory), Tsun‐Kong Sham(Western University), Edward H. Sargent(University of Toronto), David Sinton(University of Toronto)

Nature Communications

October 30, 2018

10.1038/s41467-018-07032-0

Cited by 209Open Access

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Abstract

Abstract The electrochemical reduction of carbon monoxide is a promising approach for the renewable production of carbon-based fuels and chemicals. Copper shows activity toward multi-carbon products from CO reduction, with reaction selectivity favoring two-carbon products; however, efficient conversion of CO to higher carbon products such as n-propanol, a liquid fuel, has yet to be achieved. We hypothesize that copper adparticles, possessing a high density of under-coordinated atoms, could serve as preferential sites for n-propanol formation. Density functional theory calculations suggest that copper adparticles increase CO binding energy and stabilize two-carbon intermediates, facilitating coupling between adsorbed *CO and two-carbon intermediates to form three-carbon products. We form adparticle-covered catalysts in-situ by mediating catalyst growth with strong CO chemisorption. The new catalysts exhibit an n-propanol Faradaic efficiency of 23% from CO reduction at an n-propanol partial current density of 11 mA cm −2 .

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