Research Progress on Reversible Protonic Ceramic Electrochemical Cell

被引:0
作者
Wang Z. [1 ]
Zhou X. [1 ,2 ]
Liu L. [1 ]
Chen H. [1 ]
Qian X. [1 ]
He F. [1 ]
Sheng Y. [1 ]
Jiang X. [1 ]
机构
[1] College of Chemistry and Chemical Engineering, Southwest Petroleum University, Chengdu
[2] Tianfu Yongxing Laboratory, Chengdu
来源
Kuei Suan Jen Hsueh Pao/Journal of the Chinese Ceramic Society | 2023年 / 51卷 / 10期
关键词
air electrode; electrochemical energy storage; high-temperature reversible cells; proton conductor; renewable resources;
D O I
10.14062/j.issn.0454-5648.20230062
中图分类号
学科分类号
摘要
Reversible protonic ceramic electrochemical cell (R-PCEC) is an emerging and efficient energy conversion device that can convert chemical energy into electrical energy and electrical energy into chemical energy. The reversible operation of R-PCEC in the dual mode of fuel cell and electrolytic cell is highly flexible and is one of the most promising ways for efficient energy conversion and storage. However, for R-PCEC, the electrolyte conductivity, catalytic activity of the cathode and anode, and durability under actual operating conditions are the main factors restricting its performance. This review introduced the research and development status of each component of R-PCEC in detail, including electrolyte materials, hydrogen electrodes, and air electrodes, as well as mainly focused on the latest progress on material requirements, electrode performance and reaction mechanism of air electrodes for reversible batteries. In addition, the future developments on R-PCEC were also prospected. © 2023 Chinese Ceramic Society. All rights reserved.
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页码:2689 / 2699
页数:10
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共 63 条
  • [1] YUKSEL I, KAYGUSUZ K., Renewable energy sources for clean and sustainable energy policies in Turkey[J], Renew Sustain Energy Rev, 15, 8, pp. 4132-4144, (2011)
  • [2] NI M, LEUNG M K H, LEUNG D Y C., Technological development of hydrogen production by solid oxide electrolyzer cell (SOEC)[J], Int J Hydrog Energy, 33, 9, pp. 2337-2354, (2008)
  • [3] EBBESEN S D, JENSEN S H, HAUCH A, Et al., High temperature electrolysis in alkaline cells, solid proton conducting cells, and solid oxide cells, Chem Rev, 114, 21, pp. 10697-10734, (2014)
  • [4] HAUCH A, KUNGAS R, BLENNOW P, Et al., Recent advances in solid oxide cell technology for electrolysis, Science, 370, 6513, (2020)
  • [5] SU H R, HU Y H., Degradation issues and stabilization strategies of protonic ceramic electrolysis cells for steam electrolysis[J], Energy Sci Eng, 10, 5, pp. 1706-1725, (2022)
  • [6] MOLIN S, GAZDA M, JASINSKI P., Conductivity improvement of Ce<sub>0.8</sub>Gd<sub>0.2</sub>O<sub>1.9</sub> solid electrolyte, J Rare Earths, 27, 4, pp. 655-660, (2009)
  • [7] FABBRI E, PERGOLESI D, TRAVERSA E., Materials challenges toward proton-conducting oxidefuelcells: A critical review[J], Chem Soc Rev, 39, 11, pp. 4355-4369, (2010)
  • [8] LEI L B, ZHANG J H, YUAN Z H, Et al., Progress report on proton conducting solid oxide electrolysis cells, Adv Funct Mater, 29, 37, (2019)
  • [9] GOMEZ S Y, HOTZA D., Current developments in reversible solid oxide fuel cells[J], Renew Sustain Energy Rev, 61, pp. 155-174, (2016)
  • [10] MALEROD-FJELD H, CLARK D, YUSTE-TIRADOS I, Et al., Thermo-electrochemical production of compressed hydrogen from methane with near-zero energy loss[J], Nat Energy, 2, 12, pp. 923-931, (2017)
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