Facet-switching of rate-determining step on copper in CO2-to-ethylene electroreduction
Reduction of carbon dioxide (CO2) by renewable electricity to produce multicarbon chemicals, such as ethylene (C2H4), continues to be a challenge because of insufficient Faradaic efficiency, low production rates, and complex mechanistic pathways. Here, we report that the rate-determining steps (RDS)...
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| Published in | Proceedings of the National Academy of Sciences - PNAS Vol. 121; no. 25; p. 1 |
|---|---|
| Main Authors | , , , , , , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Washington
National Academy of Sciences
18.06.2024
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| Subjects | |
| Online Access | Get full text |
| ISSN | 0027-8424 1091-6490 1091-6490 |
| DOI | 10.1073/pnas.2400546121 |
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| Abstract | Reduction of carbon dioxide (CO2) by renewable electricity to produce multicarbon chemicals, such as ethylene (C2H4), continues to be a challenge because of insufficient Faradaic efficiency, low production rates, and complex mechanistic pathways. Here, we report that the rate-determining steps (RDS) on common copper (Cu) surfaces diverge in CO2 electroreduction, leading to distinct catalytic performances. Through a combination of experimental and computational studies, we reveal that C─C bond-making is the RDS on Cu(100), whereas the protonation of *CO with adsorbed water becomes rate-limiting on Cu(111) with a higher energy barrier. On an oxide-derived Cu(100)-dominant Cu catalyst, we reach a high C2H4 Faradaic efficiency of 72%, partial current density of 359 mA cm−2, and long-term stability exceeding 100 h at 500 mA cm−2, greatly outperforming its Cu(111)-rich counterpart. We further demonstrate constant C2H4 selectivity of >60% over 70 h in a membrane electrode assembly electrolyzer with a full-cell energy efficiency of 23.4%. |
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| AbstractList | Reduction of carbon dioxide (CO2) by renewable electricity to produce multicarbon chemicals, such as ethylene (C2H4), continues to be a challenge because of insufficient Faradaic efficiency, low production rates, and complex mechanistic pathways. Here, we report that the rate-determining steps (RDS) on common copper (Cu) surfaces diverge in CO2 electroreduction, leading to distinct catalytic performances. Through a combination of experimental and computational studies, we reveal that C─C bond-making is the RDS on Cu(100), whereas the protonation of *CO with adsorbed water becomes rate-limiting on Cu(111) with a higher energy barrier. On an oxide-derived Cu(100)-dominant Cu catalyst, we reach a high C2H4 Faradaic efficiency of 72%, partial current density of 359 mA cm-2, and long-term stability exceeding 100 h at 500 mA cm-2, greatly outperforming its Cu(111)-rich counterpart. We further demonstrate constant C2H4 selectivity of >60% over 70 h in a membrane electrode assembly electrolyzer with a full-cell energy efficiency of 23.4%.Reduction of carbon dioxide (CO2) by renewable electricity to produce multicarbon chemicals, such as ethylene (C2H4), continues to be a challenge because of insufficient Faradaic efficiency, low production rates, and complex mechanistic pathways. Here, we report that the rate-determining steps (RDS) on common copper (Cu) surfaces diverge in CO2 electroreduction, leading to distinct catalytic performances. Through a combination of experimental and computational studies, we reveal that C─C bond-making is the RDS on Cu(100), whereas the protonation of *CO with adsorbed water becomes rate-limiting on Cu(111) with a higher energy barrier. On an oxide-derived Cu(100)-dominant Cu catalyst, we reach a high C2H4 Faradaic efficiency of 72%, partial current density of 359 mA cm-2, and long-term stability exceeding 100 h at 500 mA cm-2, greatly outperforming its Cu(111)-rich counterpart. We further demonstrate constant C2H4 selectivity of >60% over 70 h in a membrane electrode assembly electrolyzer with a full-cell energy efficiency of 23.4%. Reduction of carbon dioxide (CO2) by renewable electricity to produce multicarbon chemicals, such as ethylene (C2H4), continues to be a challenge because of insufficient Faradaic efficiency, low production rates, and complex mechanistic pathways. Here, we report that the rate-determining steps (RDS) on common copper (Cu) surfaces diverge in CO2 electroreduction, leading to distinct catalytic performances. Through a combination of experimental and computational studies, we reveal that C─C bond-making is the RDS on Cu(100), whereas the protonation of *CO with adsorbed water becomes rate-limiting on Cu(111) with a higher energy barrier. On an oxide-derived Cu(100)-dominant Cu catalyst, we reach a high C2H4 Faradaic efficiency of 72%, partial current density of 359 mA cm−2, and long-term stability exceeding 100 h at 500 mA cm−2, greatly outperforming its Cu(111)-rich counterpart. We further demonstrate constant C2H4 selectivity of >60% over 70 h in a membrane electrode assembly electrolyzer with a full-cell energy efficiency of 23.4%. We experimentally show that the rate-determining step (RDS) on common copper (Cu) surfaces diverge in CO 2 electroreduction, leading to distinct catalytic performance. The C─C bond-making is the RDS on Cu(100), whereas the protonation of *CO with water becomes RDS on Cu(111). On an oxide-derived Cu(100)-dominant Cu catalyst, we reach a high C 2 H 4 Faradaic efficiency of 72% (C 2+ Faradaic efficiency of about 90%), partial current density of 359 mA cm −2 , and long-term stability exceeding 100 h. Reduction of carbon dioxide (CO 2 ) by renewable electricity to produce multicarbon chemicals, such as ethylene (C 2 H 4 ), continues to be a challenge because of insufficient Faradaic efficiency, low production rates, and complex mechanistic pathways. Here, we report that the rate-determining steps (RDS) on common copper (Cu) surfaces diverge in CO 2 electroreduction, leading to distinct catalytic performances. Through a combination of experimental and computational studies, we reveal that C─C bond-making is the RDS on Cu(100), whereas the protonation of *CO with adsorbed water becomes rate-limiting on Cu(111) with a higher energy barrier. On an oxide-derived Cu(100)-dominant Cu catalyst, we reach a high C 2 H 4 Faradaic efficiency of 72%, partial current density of 359 mA cm −2 , and long-term stability exceeding 100 h at 500 mA cm −2 , greatly outperforming its Cu(111)-rich counterpart. We further demonstrate constant C 2 H 4 selectivity of >60% over 70 h in a membrane electrode assembly electrolyzer with a full-cell energy efficiency of 23.4%. |
| Author | Zhang, Yu-Cai Sun, Shu-Ping Zhang, Xiao-Long Niu, Zhuang-Zhuang Gao, Fei-Yue Yang, Peng-Peng Wu, Zhi-Zheng Wang, Ye-Hua Yu, Peng-Cheng Duanmu, Jing-Wen Chi, Li-Ping Gao, Min-Rui |
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| Copyright | Copyright National Academy of Sciences Jun 18, 2024 Copyright © 2024 the Author(s). Published by PNAS. 2024 |
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| Snippet | Reduction of carbon dioxide (CO2) by renewable electricity to produce multicarbon chemicals, such as ethylene (C2H4), continues to be a challenge because of... We experimentally show that the rate-determining step (RDS) on common copper (Cu) surfaces diverge in CO 2 electroreduction, leading to distinct catalytic... |
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| SubjectTerms | Carbon dioxide Catalysts Copper Efficiency Electrodes Electrowinning Energy efficiency Ethylene Physical Sciences Protonation |
| Title | Facet-switching of rate-determining step on copper in CO2-to-ethylene electroreduction |
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