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Decoupled hydrogen and oxygen evolution by a two-step electrochemical–chemical cycle for efficient overall water splitting

Author

Listed:
  • Hen Dotan

    (Technion—Israel Institute of Technology)

  • Avigail Landman

    (Technion—Israel Institute of Technology)

  • Stafford W. Sheehan

    (Technion—Israel Institute of Technology
    Catalytic Innovations)

  • Kirtiman Deo Malviya

    (Technion—Israel Institute of Technology)

  • Gennady E. Shter

    (Technion—Israel Institute of Technology)

  • Daniel A. Grave

    (Technion—Israel Institute of Technology)

  • Ziv Arzi

    (Technion—Israel Institute of Technology)

  • Nachshon Yehudai

    (Technion—Israel Institute of Technology)

  • Manar Halabi

    (Technion—Israel Institute of Technology)

  • Netta Gal

    (Technion—Israel Institute of Technology)

  • Noam Hadari

    (Technion—Israel Institute of Technology)

  • Coral Cohen

    (Technion—Israel Institute of Technology)

  • Avner Rothschild

    (Technion—Israel Institute of Technology)

  • Gideon S. Grader

    (Technion—Israel Institute of Technology)

Abstract

Electrolytic hydrogen production faces technological challenges to improve its efficiency, economic value and potential for global integration. In conventional water electrolysis, the water oxidation and reduction reactions are coupled in both time and space, as they occur simultaneously at an anode and a cathode in the same cell. This introduces challenges, such as product separation, and sets strict constraints on material selection and process conditions. Here, we decouple these reactions by dividing the process into two steps: an electrochemical step that reduces water at the cathode and oxidizes the anode, followed by a spontaneous chemical step that is driven faster at higher temperature, which reduces the anode back to its initial state by oxidizing water. This enables overall water splitting at average cell voltages of 1.44–1.60 V with nominal current densities of 10–200 mA cm−2 in a membrane-free, two-electrode cell. This allows us to produce hydrogen at low voltages in a simple, cyclic process with high efficiency, robustness, safety and scale-up potential.

Suggested Citation

  • Hen Dotan & Avigail Landman & Stafford W. Sheehan & Kirtiman Deo Malviya & Gennady E. Shter & Daniel A. Grave & Ziv Arzi & Nachshon Yehudai & Manar Halabi & Netta Gal & Noam Hadari & Coral Cohen & Avn, 2019. "Decoupled hydrogen and oxygen evolution by a two-step electrochemical–chemical cycle for efficient overall water splitting," Nature Energy, Nature, vol. 4(9), pages 786-795, September.
    • Handle: RePEc:nat:natene:v:4:y:2019:i:9:d:10.1038_s41560-019-0462-7
    DOI: 10.1038/s41560-019-0462-7
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    Cited by:

    1. Qian Dang & Haiping Lin & Zhenglong Fan & Lu Ma & Qi Shao & Yujin Ji & Fangfang Zheng & Shize Geng & Shi-Ze Yang & Ningning Kong & Wenxiang Zhu & Youyong Li & Fan Liao & Xiaoqing Huang & Mingwang Shao, 2021. "Iridium metallene oxide for acidic oxygen evolution catalysis," Nature Communications, Nature, vol. 12(1), pages 1-10, December.
    2. Yong Zuo & Sebastiano Bellani & Michele Ferri & Gabriele Saleh & Dipak V. Shinde & Marilena Isabella Zappia & Rosaria Brescia & Mirko Prato & Luca Trizio & Ivan Infante & Francesco Bonaccorso & Libera, 2023. "High-performance alkaline water electrolyzers based on Ru-perturbed Cu nanoplatelets cathode," Nature Communications, Nature, vol. 14(1), pages 1-15, December.
    3. Liu-Chun Wang & Pei-Yu Chiou & Ya-Ping Hsu & Chin-Lai Lee & Chih-Hsuan Hung & Yi-Hsuan Wu & Wen-Jyun Wang & Gia-Ling Hsieh & Ying-Chi Chen & Li-Chan Chang & Wen-Pin Su & Divinah Manoharan & Min-Chiao , 2023. "Prussian blue analog with separated active sites to catalyze water driven enhanced catalytic treatments," Nature Communications, Nature, vol. 14(1), pages 1-16, December.
    4. Yang, Wei & Bao, Jingjing & Liu, Hongtao & Zhang, Jun & Guo, Lin, 2023. "Low-grade heat to hydrogen: Current technologies, challenges and prospective," Renewable and Sustainable Energy Reviews, Elsevier, vol. 188(C).
    5. Zhao, Meng-Jie & He, Qian & Xiang, Ting & Ya, Hua-Qin & Luo, Hao & Wan, Shanhong & Ding, Jun & He, Jian-Bo, 2023. "Automatic operation of decoupled water electrolysis based on bipolar electrode," Renewable Energy, Elsevier, vol. 203(C), pages 583-591.
    6. Fan Liao & Kui Yin & Yujin Ji & Wenxiang Zhu & Zhenglong Fan & Youyong Li & Jun Zhong & Mingwang Shao & Zhenhui Kang & Qi Shao, 2023. "Iridium oxide nanoribbons with metastable monoclinic phase for highly efficient electrocatalytic oxygen evolution," Nature Communications, Nature, vol. 14(1), pages 1-11, December.
    7. Yuandong Yan & Ruyi Wang & Qian Zheng & Jiaying Zhong & Weichang Hao & Shicheng Yan & Zhigang Zou, 2023. "Nonredox trivalent nickel catalyzing nucleophilic electrooxidation of organics," Nature Communications, Nature, vol. 14(1), pages 1-11, December.
    8. Xin Kang & Fengning Yang & Zhiyuan Zhang & Heming Liu & Shiyu Ge & Shuqi Hu & Shaohai Li & Yuting Luo & Qiangmin Yu & Zhibo Liu & Qiang Wang & Wencai Ren & Chenghua Sun & Hui-Ming Cheng & Bilu Liu, 2023. "A corrosion-resistant RuMoNi catalyst for efficient and long-lasting seawater oxidation and anion exchange membrane electrolyzer," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    9. Fernando Rocha & Christos Georgiadis & Kevin Droogenbroek & Renaud Delmelle & Xavier Pinon & Grzegorz Pyka & Greet Kerckhofs & Franz Egert & Fatemeh Razmjooei & Syed-Asif Ansar & Shigenori Mitsushima , 2024. "Proton exchange membrane-like alkaline water electrolysis using flow-engineered three-dimensional electrodes," Nature Communications, Nature, vol. 15(1), pages 1-13, December.

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