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Bridging the gap between highly active oxygen reduction reaction catalysts and effective catalyst layers for proton exchange membrane fuel cells

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  • Jiantao Fan

    (Southern University of Science and Technology
    Southern University of Science and Technology
    Guangdong Provincial Key Laboratory of Energy Materials for Electric Power)

  • Ming Chen

    (Guangdong Provincial Key Laboratory of Energy Materials for Electric Power
    Southern University of Science and Technology)

  • Zhiliang Zhao

    (Southern University of Science and Technology
    Guangdong Provincial Key Laboratory of Energy Materials for Electric Power)

  • Zhen Zhang

    (Southern University of Science and Technology
    Guangdong Provincial Key Laboratory of Energy Materials for Electric Power)

  • Siyu Ye

    (Guangzhou University
    SinoHykey Technology Guangzhou Co. Ltd)

  • Shaoyi Xu

    (Southern University of Science and Technology
    Southern University of Science and Technology
    Guangdong Provincial Key Laboratory of Energy Materials for Electric Power)

  • Haijiang Wang

    (Guangdong Provincial Key Laboratory of Energy Materials for Electric Power
    Southern University of Science and Technology)

  • Hui Li

    (Southern University of Science and Technology
    Guangdong Provincial Key Laboratory of Energy Materials for Electric Power)

Abstract

Ultralow platinum loading and high catalytic performance at the membrane electrode assembly (MEA) level are essential for reducing the cost of proton exchange membrane fuel cells. The past decade has seen substantial progress in developing a variety of highly active platinum-based catalysts for the oxygen reduction reaction. However, these high activities are almost exclusively obtained from rotating disk electrode (RDE) measurements and have rarely translated into MEA performance. In this Review, we elucidate the intrinsic limitations that lead to a persistent failure to transfer catalysts’ high RDE activities into maximized MEA performance. We discuss catalyst-layer engineering strategies for controlling mass transport resistances at local catalyst sites, in the bulk of the catalyst layer and at the interfaces of the MEA to achieve high performance with ultralow platinum loading. We also examine promising intermediate testing methods for closing the gap between RDE and MEA experiments.

Suggested Citation

  • Jiantao Fan & Ming Chen & Zhiliang Zhao & Zhen Zhang & Siyu Ye & Shaoyi Xu & Haijiang Wang & Hui Li, 2021. "Bridging the gap between highly active oxygen reduction reaction catalysts and effective catalyst layers for proton exchange membrane fuel cells," Nature Energy, Nature, vol. 6(5), pages 475-486, May.
    • Handle: RePEc:nat:natene:v:6:y:2021:i:5:d:10.1038_s41560-021-00824-7
    DOI: 10.1038/s41560-021-00824-7
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    Cited by:

    1. Chongyang Tang & Cong Wei & Yanyan Fang & Bo Liu & Xianyin Song & Zenan Bian & Xuanwei Yin & Hongbo Wang & Zhaohui Liu & Gongming Wang & Xiangheng Xiao & Xiangfeng Duan, 2024. "Electrocatalytic hydrogenation of acetonitrile to ethylamine in acid," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    2. Zhang, Yong & He, Shirong & Jiang, Xiaohui & Wang, Zhuo & Wang, Yonggang & Gu, Meng & Yang, Xi & Zhang, Shuanyang & Cao, Jing & Fang, Haoyan & Li, Qiming, 2024. "Performance and configuration optimization of proton exchange membrane fuel cell considering dual symmetric Tesla valve flow field," Energy, Elsevier, vol. 288(C).
    3. Lei Huang & Min Wei & Ruijuan Qi & Chung-Li Dong & Dai Dang & Cheng-Chieh Yang & Chenfeng Xia & Chao Chen & Shahid Zaman & Fu-Min Li & Bo You & Bao Yu Xia, 2022. "An integrated platinum-nanocarbon electrocatalyst for efficient oxygen reduction," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    4. Zhang, Yong & He, Shirong & Jiang, Xiaohui & Wang, Zhuo & Yang, Xi & Fang, Haoyan & Li, Qiming & Cao, Jing, 2024. "Investigation on performance of full-scale proton exchange membrane fuel cell: Porous foam flow field with integrated bipolar plate/gas diffusion layer," Energy, Elsevier, vol. 287(C).
    5. Peng Zhang & Hsiao-Chien Chen & Houyu Zhu & Kuo Chen & Tuya Li & Yilin Zhao & Jiaye Li & Ruanbo Hu & Siying Huang & Wei Zhu & Yunqi Liu & Yuan Pan, 2024. "Inter-site structural heterogeneity induction of single atom Fe catalysts for robust oxygen reduction," Nature Communications, Nature, vol. 15(1), pages 1-14, December.
    6. Lei Wan & Maobin Pang & Junfa Le & Ziang Xu & Hangyu Zhou & Qin Xu & Baoguo Wang, 2022. "Oriented intergrowth of the catalyst layer in membrane electrode assembly for alkaline water electrolysis," Nature Communications, Nature, vol. 13(1), pages 1-12, December.
    7. Lin, P.Z. & Sun, J. & He, C.X. & Wu, M.C. & Zhao, T.S., 2024. "Modeling proton exchange membrane fuel cells with platinum-group-metal-free catalysts," Applied Energy, Elsevier, vol. 360(C).
    8. Yongqiang Li & Siwei Yang & Wancheng Bao & Quan Tao & Xiuyun Jiang & Jipeng Li & Peng He & Gang Wang & Kai Qi & Hui Dong & Guqiao Ding & Xiaoming Xie, 2024. "Accelerated proton dissociation in an excited state induces superacidic microenvironments around graphene quantum dots," Nature Communications, Nature, vol. 15(1), pages 1-13, December.
    9. Javaid, Usman & Mehmood, Adeel & Iqbal, Jamshed & Uppal, Ali Arshad, 2023. "Neural network and URED observer based fast terminal integral sliding mode control for energy efficient polymer electrolyte membrane fuel cell used in vehicular technologies," Energy, Elsevier, vol. 269(C).
    10. Donglai Pan & Muthu Austeria P & Shinbi Lee & Ho-sub Bae & Fei He & Geun Ho Gu & Wonyong Choi, 2024. "Integrated electrocatalytic synthesis of ammonium nitrate from dilute NO gas on metal organic frameworks-modified gas diffusion electrodes," Nature Communications, Nature, vol. 15(1), pages 1-15, December.
    11. Lingyou Zeng & Zhonglong Zhao & Fan Lv & Zhonghong Xia & Shi-Yu Lu & Jiong Li & Kaian Sun & Kai Wang & Yingjun Sun & Qizheng Huang & Yan Chen & Qinghua Zhang & Lin Gu & Gang Lu & Shaojun Guo, 2022. "Anti-dissolution Pt single site with Pt(OH)(O3)/Co(P) coordination for efficient alkaline water splitting electrolyzer," Nature Communications, Nature, vol. 13(1), pages 1-9, December.

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