Micromodification of the Catalyst Layer by CO to Increase Pt Utilization for Proton-Exchange Membrane Fuel Cells

被引:6
|
作者
Wen, Zengyin [1 ]
Wu, Duojie [1 ]
Banham, Dustin [2 ,3 ,4 ]
Chen, Ming [5 ]
Sun, Fengman [6 ]
Zhao, Zhiliang [1 ]
Jin, Yiqi [1 ]
Fan, Li [1 ]
Xu, Shaoyi [1 ,7 ]
Gu, Meng [1 ]
Fan, Jiantao [7 ,8 ]
Li, Hui [1 ,9 ,10 ]
机构
[1] Southern Univ Sci & Technol, Dept Mat Sci & Engn, Shenzhen 518055, Peoples R China
[2] Foshan Univ, Sch Mat Sci & Hydrogen Energy, Foshan 528000, Peoples R China
[3] Guangdong Key Lab Hydrogen Energy Technol, Foshan 528000, Peoples R China
[4] Guangdong TaiJi Power, Foshan 528000, Peoples R China
[5] Southern Univ Sci & Technol, Dept Mech & Energy Engn, Shenzhen 518055, Peoples R China
[6] Harbin Inst Technol, Harbin 150001, Peoples R China
[7] Southern Univ Sci & Technol, Acad Adv Interdisciplinary Studies, Shenzhen 518055, Guangdong, Peoples R China
[8] Southern Univ Sci & Technol, Guangdong Prov Key Lab Energy Mat Elect Power, Shenzhen 518055, Peoples R China
[9] Southern Univ Sci & Technol, Key Univ Lab Highly Efficient Utilizat Solar Ener, Shenzhen 518055, Peoples R China
[10] Southern Univ Sci & Technol, Shenzhen Key Lab Hydrogen Energy, Shenzhen 518055, Peoples R China
来源
ACS APPLIED MATERIALS & INTERFACES | 2023年 / 15卷 / 01期
关键词
Pt utilization; ionomer distribution; mass transport resistance; micromodification; CO adsorption; OXYGEN-TRANSPORT RESISTANCE; DIFFUSION RESISTANCE; IONOMER; PERFORMANCE; REDUCTION; SURFACE; NAFION; PERMEABILITY; VOLTAMMETRY; ELECTRODES;
D O I
10.1021/acsami.2c16524
中图分类号
TB3 [工程材料学];
学科分类号
0805 ; 080502 ;
摘要
Improving the utilization of platinum in proton-exchange membrane (PEM) fuel cells is critical to reducing their cost. In the past decade, numerous Pt-based oxygen reduction reaction catalysts with high specific and mass activities have been developed. However, the high activities are mostly achieved in rotating disk electrode (RDE) measurement and have rarely been accomplished at the membrane electrode assembly (MEA) level. The failure of these direct translations from RDE to MEA has been well documented with several key reasons having been previously identified. One of them is the resistance caused by complex mass transport pathways in the MEA. Herein, we improve the proton and oxygen transportations in the MEA by building a thin and uniform distribution of ionomer on the catalyst surface. As a result, a PEM fuel cell design is capable of showing a current density improvement of 38% at the same voltage (0.6 V) under the H-2/air operation.
引用
收藏
页码:903 / 913
页数:11
相关论文
共 50 条
  • [41] Designing the next generation of proton-exchange membrane fuel cells
    Kui Jiao
    Jin Xuan
    Qing Du
    Zhiming Bao
    Biao Xie
    Bowen Wang
    Yan Zhao
    Linhao Fan
    Huizhi Wang
    Zhongjun Hou
    Sen Huo
    Nigel P. Brandon
    Yan Yin
    Michael D. Guiver
    Nature, 2021, 595 : 361 - 369
  • [42] Enhancing the performance of proton-exchange membrane fuel cell by optimizing the hydrophobicity and porosity of cathode catalyst layer
    Zhang, Yan
    Jia, Puping
    Yang, Suyi
    Su, Jinzhan
    Guo, Liejin
    SCIENCE CHINA-TECHNOLOGICAL SCIENCES, 2025, 68 (03)
  • [43] Recent advances in the anode catalyst layer for proton exchange membrane fuel cells
    Li, Zheng
    Wang, Yameng
    Mu, Yongbiao
    Wu, Buke
    Jiang, Yuting
    Zeng, Lin
    Zhao, Tianshou
    RENEWABLE & SUSTAINABLE ENERGY REVIEWS, 2023, 176
  • [44] Preparation and Characterization of Nanofiber Catalyst Layer for Proton Exchange Membrane Fuel Cells
    Zhang, Qin-guo
    Tong, Shui-guang
    Tong, Zhe-ming
    Cheng, Zhe-wu
    ECS JOURNAL OF SOLID STATE SCIENCE AND TECHNOLOGY, 2020, 9 (05)
  • [45] Possible scenario of forming a catalyst layer for proton exchange membrane fuel cells
    Zeng, R.
    Zhang, H. Y.
    Liang, S. Z.
    Wang, L. G.
    Jiang, L. J.
    Liu, X. P.
    RSC ADVANCES, 2020, 10 (09) : 5502 - 5506
  • [46] Influence of the water uptake in the catalyst layer for the proton exchange membrane fuel cells
    Jung, Chi-Young
    Yi, Sung-Chul
    ELECTROCHEMISTRY COMMUNICATIONS, 2013, 35 : 34 - 37
  • [47] Effects of Gas-Diffusion Layers and Water Management on the Carbon Corrosion of a Catalyst Layer in Proton-Exchange Membrane Fuel Cells
    Lee, Sumin
    Kim, Changki
    Lee, Eunjik
    Choi, Yoon-Young
    Jung, Sung Yong
    Sohn, Young-Jun
    Oh, Hwanyeong
    INTERNATIONAL JOURNAL OF ENERGY RESEARCH, 2024, 2024
  • [48] Gradient Hydrophobic Microporous Layer for High-Performance Proton-Exchange Membrane Fuel Cells
    Wang, Wei
    Guo, Jie
    Gu, Tianyi
    Shi, Ruhua
    Wei, Xian
    Zhang, Qian
    Wang, Haibo
    Yang, Ruizhi
    ENERGY & FUELS, 2024, 38 (03) : 2368 - 2376
  • [49] Understanding and Engineering of Multiphase Transport Processes in Membrane Electrode Assembly of Proton-Exchange Membrane Fuel Cells with a Focus on the Cathode Catalyst Layer: A Review
    Deng, Xiang
    Zhang, Jun
    Fan, Ziyi
    Tan, Wenyi
    Yang, Guangming
    Wang, Wei
    Zhou, Wei
    Shao, Zongping
    ENERGY & FUELS, 2020, 34 (08) : 9175 - 9188
  • [50] Self-humidifying Pt-C/Pt-TiO2 dual-catalyst electrode membrane assembly for proton-exchange membrane fuel cells
    Yang, H. N.
    Lee, W. H.
    Choi, B. S.
    Ko, Y. D.
    Yi, S. C.
    Kim, W. J.
    ENERGY, 2017, 120 : 12 - 19
12345