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Accelerating electrochemical CO2 reduction to multi-carbon products via asymmetric intermediate binding at confined nanointerfaces

Author

Listed:
  • Jin Zhang

    (Nanjing University)

  • Chenxi Guo

    (Dalian Institute of Chemical Physics, Chinese Academy of Sciences)

  • Susu Fang

    (Nanjing University)

  • Xiaotong Zhao

    (Nanjing University)

  • Le Li

    (Nanjing University)

  • Haoyang Jiang

    (Nanjing University)

  • Zhaoyang Liu

    (Nanjing University)

  • Ziqi Fan

    (Nanjing University)

  • Weigao Xu

    (Nanjing University)

  • Jianping Xiao

    (Dalian Institute of Chemical Physics, Chinese Academy of Sciences
    University of Chinese Academy of Sciences)

  • Miao Zhong

    (Nanjing University)

Abstract

Electrochemical CO2 reduction (CO2R) to ethylene and ethanol enables the long-term storage of renewable electricity in valuable multi-carbon (C2+) chemicals. However, carbon–carbon (C–C) coupling, the rate-determining step in CO2R to C2+ conversion, has low efficiency and poor stability, especially in acid conditions. Here we find that, through alloying strategies, neighbouring binary sites enable asymmetric CO binding energies to promote CO2-to-C2+ electroreduction beyond the scaling-relation-determined activity limits on single-metal surfaces. We fabricate experimentally a series of Zn incorporated Cu catalysts that show increased asymmetric CO* binding and surface CO* coverage for fast C–C coupling and the consequent hydrogenation under electrochemical reduction conditions. Further optimization of the reaction environment at nanointerfaces suppresses hydrogen evolution and improves CO2 utilization under acidic conditions. We achieve, as a result, a high 31 ± 2% single-pass CO2-to-C2+ yield in a mild-acid pH 4 electrolyte with >80% single-pass CO2 utilization efficiency. In a single CO2R flow cell electrolyzer, we realize a combined performance of 91 ± 2% C2+ Faradaic efficiency with notable 73 ± 2% ethylene Faradaic efficiency, 31 ± 2% full-cell C2+ energy efficiency, and 24 ± 1% single-pass CO2 conversion at a commercially relevant current density of 150 mA cm−2 over 150 h.

Suggested Citation

  • Jin Zhang & Chenxi Guo & Susu Fang & Xiaotong Zhao & Le Li & Haoyang Jiang & Zhaoyang Liu & Ziqi Fan & Weigao Xu & Jianping Xiao & Miao Zhong, 2023. "Accelerating electrochemical CO2 reduction to multi-carbon products via asymmetric intermediate binding at confined nanointerfaces," Nature Communications, Nature, vol. 14(1), pages 1-11, December.
  • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-36926-x
    DOI: 10.1038/s41467-023-36926-x
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    References listed on IDEAS

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    Cited by:

    1. Xiaohan Yu & Yuting Xu & Le Li & Mingzhe Zhang & Wenhao Qin & Fanglin Che & Miao Zhong, 2024. "Coverage enhancement accelerates acidic CO2 electrolysis at ampere-level current with high energy and carbon efficiencies," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    2. Kang Yang & Ming Li & Tianqi Gao & Guoliang Xu & Di Li & Yao Zheng & Qiang Li & Jingjing Duan, 2024. "An acid-tolerant metal-organic framework for industrial CO2 electrolysis using a proton exchange membrane," Nature Communications, Nature, vol. 15(1), pages 1-12, December.
    3. Jiaqi Feng & Limin Wu & Xinning Song & Libing Zhang & Shunhan Jia & Xiaodong Ma & Xingxing Tan & Xinchen Kang & Qinggong Zhu & Xiaofu Sun & Buxing Han, 2024. "CO2 electrolysis to multi-carbon products in strong acid at ampere-current levels on La-Cu spheres with channels," Nature Communications, Nature, vol. 15(1), pages 1-11, December.

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