Scholars@Duke publication: Efficient electrically powered CO<inf>2</inf>-to-ethanol via suppression of deoxygenation

Efficient electrically powered CO2-to-ethanol via suppression of deoxygenation

Publication , Journal Article

Wang, X; Wang, Z; García de Arquer, FP; Dinh, CT; Ozden, A; Li, YC; Nam, DH; Li, J; Liu, YS; Wicks, J; Chen, Z; Chi, M; Chen, B; Wang, Y ...

Published in: Nature Energy

June 1, 2020

Published version (DOI)

The carbon dioxide electroreduction reaction (CO2RR) provides ways to produce ethanol but its Faradaic efficiency could be further improved, especially in CO2RR studies reported at a total current density exceeding 10 mA cm−2. Here we report a class of catalysts that achieve an ethanol Faradaic efficiency of (52 ± 1)% and an ethanol cathodic energy efficiency of 31%. We exploit the fact that suppression of the deoxygenation of the intermediate HOCCH* to ethylene promotes ethanol production, and hence that confinement using capping layers having strong electron-donating ability on active catalysts promotes C–C coupling and increases the reaction energy of HOCCH* deoxygenation. Thus, we have developed an electrocatalyst with confined reaction volume by coating Cu catalysts with nitrogen-doped carbon. Spectroscopy suggests that the strong electron-donating ability and confinement of the nitrogen-doped carbon layers leads to the observed pronounced selectivity towards ethanol.

Duke Scholars

Author Miaofang Chi Thomas Lord Department of Mechanical Engineering and Materia ...

Altmetric Attention Stats

Dimensions Citation Stats

Published In

Nature Energy

DOI

10.1038/s41560-020-0607-8

EISSN

2058-7546

Publication Date

June 1, 2020

Volume

Issue

Start / End Page

478 / 486

Related Subject Headings

4017 Mechanical engineering
4008 Electrical engineering
0907 Environmental Engineering
0906 Electrical and Electronic Engineering

Citation

APA

Chicago

ICMJE

MLA

NLM

Wang, X., Wang, Z., García de Arquer, F. P., Dinh, C. T., Ozden, A., Li, Y. C., … Sargent, E. H. (2020). Efficient electrically powered CO2-to-ethanol via suppression of deoxygenation. Nature Energy, 5(6), 478–486. https://doi.org/10.1038/s41560-020-0607-8

Wang, X., Z. Wang, F. P. García de Arquer, C. T. Dinh, A. Ozden, Y. C. Li, D. H. Nam, et al. “Efficient electrically powered CO2-to-ethanol via suppression of deoxygenation.” Nature Energy 5, no. 6 (June 1, 2020): 478–86. https://doi.org/10.1038/s41560-020-0607-8.

Wang X, Wang Z, García de Arquer FP, Dinh CT, Ozden A, Li YC, et al. Efficient electrically powered CO2-to-ethanol via suppression of deoxygenation. Nature Energy. 2020 Jun 1;5(6):478–86.

Wang, X., et al. “Efficient electrically powered CO2-to-ethanol via suppression of deoxygenation.” Nature Energy, vol. 5, no. 6, June 2020, pp. 478–86. Scopus, doi:10.1038/s41560-020-0607-8.

Wang X, Wang Z, García de Arquer FP, Dinh CT, Ozden A, Li YC, Nam DH, Li J, Liu YS, Wicks J, Chen Z, Chi M, Chen B, Wang Y, Tam J, Howe JY, Proppe A, Todorović P, Li F, Zhuang TT, Gabardo CM, Kirmani AR, McCallum C, Hung SF, Lum Y, Luo M, Min Y, Xu A, O’Brien CP, Stephen B, Sun B, Ip AH, Richter LJ, Kelley SO, Sinton D, Sargent EH. Efficient electrically powered CO2-to-ethanol via suppression of deoxygenation. Nature Energy. 2020 Jun 1;5(6):478–486.

Published In

Nature Energy

DOI

10.1038/s41560-020-0607-8

EISSN

2058-7546

Publication Date

June 1, 2020

Volume

Issue

Start / End Page

478 / 486

Related Subject Headings

4017 Mechanical engineering
4008 Electrical engineering
0907 Environmental Engineering
0906 Electrical and Electronic Engineering