Hydroxide promotes carbon dioxide electroreduction to ethanol on copper via tuning of adsorbed hydrogen

Mingchuan Luo; Ziyun Wang; Yuguang C. Li; Jun Li; Fengwang Li; Yanwei Lum; Dae Hyun Nam; Bin Chen; Joshua Wicks; Aoni Xu; Taotao Zhuang; Wan Ru Leow; Xue Wang; Cao Thang Dinh; Ying Wang; Yuhang Wang; David Sinton; Edward H. Sargent

doi:10.1038/s41467-019-13833-8

Hydroxide promotes carbon dioxide electroreduction to ethanol on copper via tuning of adsorbed hydrogen

Mingchuan Luo
, Ziyun Wang
, Yuguang C. Li
, Jun Li
, Fengwang Li
, Yanwei Lum
, Dae Hyun Nam
, Bin Chen
, Joshua Wicks
, Aoni Xu
, Taotao Zhuang
, Wan Ru Leow
, Xue Wang
, Cao Thang Dinh
, Ying Wang
, Yuhang Wang
, David Sinton
, Edward H. Sargent

Department of Energy and Science and Engineering

University of Toronto

Research output: Contribution to journal › Article › peer-review

333 Scopus citations

Abstract

Producing liquid fuels such as ethanol from CO₂, H₂O, and renewable electricity offers a route to store sustainable energy. The search for efficient electrocatalysts for the CO₂ reduction reaction relies on tuning the adsorption strength of carbonaceous intermediates. Here, we report a complementary approach in which we utilize hydroxide and oxide doping of a catalyst surface to tune the adsorbed hydrogen on Cu. Density functional theory studies indicate that this doping accelerates water dissociation and changes the hydrogen adsorption energy on Cu. We synthesize and investigate a suite of metal-hydroxide-interface-doped-Cu catalysts, and find that the most efficient, Ce(OH)_x-doped-Cu, exhibits an ethanol Faradaic efficiency of 43% and a partial current density of 128 mA cm⁻². Mechanistic studies, wherein we combine investigation of hydrogen evolution performance with the results of operando Raman spectroscopy, show that adsorbed hydrogen hydrogenates surface *HCCOH, a key intermediate whose fate determines branching to ethanol versus ethylene.

Original language	English
Article number	5814
Journal	Nature Communications
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41467-019-13833-8
State	Published - 1 Dec 2019

Bibliographical note

Publisher Copyright:
© 2019, The Author(s).

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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Luo, M., Wang, Z., Li, Y. C., Li, J., Li, F., Lum, Y., Nam, D. H., Chen, B., Wicks, J., Xu, A., Zhuang, T., Leow, W. R., Wang, X., Dinh, C. T., Wang, Y., Wang, Y., Sinton, D., & Sargent, E. H. (2019). Hydroxide promotes carbon dioxide electroreduction to ethanol on copper via tuning of adsorbed hydrogen. Nature Communications, 10(1), Article 5814. https://doi.org/10.1038/s41467-019-13833-8

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title = "Hydroxide promotes carbon dioxide electroreduction to ethanol on copper via tuning of adsorbed hydrogen",

abstract = "Producing liquid fuels such as ethanol from CO2, H2O, and renewable electricity offers a route to store sustainable energy. The search for efficient electrocatalysts for the CO2 reduction reaction relies on tuning the adsorption strength of carbonaceous intermediates. Here, we report a complementary approach in which we utilize hydroxide and oxide doping of a catalyst surface to tune the adsorbed hydrogen on Cu. Density functional theory studies indicate that this doping accelerates water dissociation and changes the hydrogen adsorption energy on Cu. We synthesize and investigate a suite of metal-hydroxide-interface-doped-Cu catalysts, and find that the most efficient, Ce(OH)x-doped-Cu, exhibits an ethanol Faradaic efficiency of 43\% and a partial current density of 128 mA cm−2. Mechanistic studies, wherein we combine investigation of hydrogen evolution performance with the results of operando Raman spectroscopy, show that adsorbed hydrogen hydrogenates surface *HCCOH, a key intermediate whose fate determines branching to ethanol versus ethylene.",

author = "Mingchuan Luo and Ziyun Wang and Li, \{Yuguang C.\} and Jun Li and Fengwang Li and Yanwei Lum and Nam, \{Dae Hyun\} and Bin Chen and Joshua Wicks and Aoni Xu and Taotao Zhuang and Leow, \{Wan Ru\} and Xue Wang and Dinh, \{Cao Thang\} and Ying Wang and Yuhang Wang and David Sinton and Sargent, \{Edward H.\}",

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doi = "10.1038/s41467-019-13833-8",

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AU - Luo, Mingchuan

AU - Wang, Ziyun

AU - Li, Yuguang C.

AU - Li, Jun

AU - Li, Fengwang

AU - Lum, Yanwei

AU - Nam, Dae Hyun

AU - Chen, Bin

AU - Wicks, Joshua

AU - Xu, Aoni

AU - Zhuang, Taotao

AU - Leow, Wan Ru

AU - Wang, Xue

AU - Dinh, Cao Thang

AU - Wang, Ying

AU - Wang, Yuhang

AU - Sinton, David

AU - Sargent, Edward H.

PY - 2019/12/1

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N2 - Producing liquid fuels such as ethanol from CO2, H2O, and renewable electricity offers a route to store sustainable energy. The search for efficient electrocatalysts for the CO2 reduction reaction relies on tuning the adsorption strength of carbonaceous intermediates. Here, we report a complementary approach in which we utilize hydroxide and oxide doping of a catalyst surface to tune the adsorbed hydrogen on Cu. Density functional theory studies indicate that this doping accelerates water dissociation and changes the hydrogen adsorption energy on Cu. We synthesize and investigate a suite of metal-hydroxide-interface-doped-Cu catalysts, and find that the most efficient, Ce(OH)x-doped-Cu, exhibits an ethanol Faradaic efficiency of 43% and a partial current density of 128 mA cm−2. Mechanistic studies, wherein we combine investigation of hydrogen evolution performance with the results of operando Raman spectroscopy, show that adsorbed hydrogen hydrogenates surface *HCCOH, a key intermediate whose fate determines branching to ethanol versus ethylene.

AB - Producing liquid fuels such as ethanol from CO2, H2O, and renewable electricity offers a route to store sustainable energy. The search for efficient electrocatalysts for the CO2 reduction reaction relies on tuning the adsorption strength of carbonaceous intermediates. Here, we report a complementary approach in which we utilize hydroxide and oxide doping of a catalyst surface to tune the adsorbed hydrogen on Cu. Density functional theory studies indicate that this doping accelerates water dissociation and changes the hydrogen adsorption energy on Cu. We synthesize and investigate a suite of metal-hydroxide-interface-doped-Cu catalysts, and find that the most efficient, Ce(OH)x-doped-Cu, exhibits an ethanol Faradaic efficiency of 43% and a partial current density of 128 mA cm−2. Mechanistic studies, wherein we combine investigation of hydrogen evolution performance with the results of operando Raman spectroscopy, show that adsorbed hydrogen hydrogenates surface *HCCOH, a key intermediate whose fate determines branching to ethanol versus ethylene.

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JO - Nature Communications

JF - Nature Communications

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Hydroxide promotes carbon dioxide electroreduction to ethanol on copper via tuning of adsorbed hydrogen

Abstract

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