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聚电解质燃料电池中的质子交换膜研究进展 被引量:1

Advances in proton exchange membranes in polyelectrolyte fuel cells
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摘要 聚电解质燃料电池(polyelectrolyte fuel cells,PEFCs)是汽车、固定式和便携式应用中极具前途的可清洁发电设备.质子交换膜是PEFCs中的重要组成部分之一.它在电池中起着阻隔燃料、传递质子的作用,其性能的优劣会直接影响PEFCs高效、稳定的运行.本综述主要总结了近20年质子交换膜的发展历程,从PEFCs的工作原理出发,首先引出质子交换膜在PEFCs中的重要作用,然后考察了质子交换膜的结构特点及其应用于PEFCs的传质特性.重点强调了质子交换膜结构对低温PEFCs性能的影响,主要包括全氟质子交换膜、含氟质子交换膜和非氟质子交换膜,以及近期开发的新一代质子交换膜.在低温质子交换膜的基础之上,还针对高温PEFCs介绍了高温质子交换膜的发展和面临的挑战.最后,展望并预测了未来质子交换膜的发展方向. Polyelectrolyte fuel cells(PEFCs)are promising devices for clean power generation in automotive,stationary,and portable applications.As a transition,the proton exchange membrane(PEM)is one of the important components in PEFCs,always promotes H+ion transport,isolates the reaction gas(H2and O2),and prevents electronic transmission between cathodes and anodes.Therefore,the performance of PEMs will directly affect the efficiency and stability of PEFCs,and the PEM with excellent performance is of great significance to PEFCs.Generally,PEMs should have extremely low gas permeability,high ion conductivity,fast water transmission and electrical insulation.To achieve this goal,PEM materials usually consist of three parts:Main chains,fixed groups,and ion exchange groups.Ion exchange groups provide faster ion transmission,while main chains and fixed groups endow PEMs with excellent chemical and mechanical stability for more stable mass transport in proton exchange membrane fuel cells(PEMFCs).Nowadays,due to better microphase separation(ordered arrangement between hydrophobic backbones and hydrophilic side chains),perfluorosulfonic acid(PFSA)membranes are the most widely used and commercialized PEMs.Moreover,to reduce the cost of PEMs,fluorine-containing PEMs and non-fluorine PEMs have been well developed.Specifically,the fluorine-containing PEMs with better microphase separation,fabricated by Suzuki-Miyaura coupling reactions or superacid catalysis methods,can provide high H+conductivity and low cost.Surprisingly,some research has broken through the original H+ion transport mechanism(Vehicular and Grotthuss mechanisms)and effectively improved the H+ion transport rate by the modification of ion channels,such as polyrotaxane prepared via host-guest interactions,COFsPEMs and PIMs-PEMs.This review mainly summarizes the research advances in PEMs in the past two decades.It starts from the principle of PEFCs and the important role of PEMs in PEFCs.The structural characteristics and mass transport characteristics of PEMs are then investigated while emphasizing the influence of molecular structures on the performance of PEFCs,mainly including PFSAPEMs,fluorine-containing PEMs and non-fluorine PEMs,as well as the recently developed new generation PEMs(polyrotaxane,COFs-PEMs and PIMs-PEMs).Meanwhile,the development and challenges of hightemperature proton exchange membranes(HT-PEMs)are introduced.HT-PEMs can effectively extend the operating temperature range of PEMFCs.HT-PEMFCs have attracted more attention due to several advantages,including improved electrode reaction kinetics,enhanced tolerance to fuel/air impurities,simple plate design,and better heat/water management.These advantages may mean the potential for using low Pt metal loading or even Pt metal free catalysts.Finally,according to the study of PEMs in recent years,this review looks forward to and predicts the direction of lowcost,high-performance PEMs in future.Up to now,although PEMs have been well developed,some performances are still not enough for the harsh environment during fuel cell operation,such as poor resistance to free radical,trade-off effects between cost and performance,and so on.Therefore,the development of PEMs should not only improve the H+ionic conductivity,but also enhance the synergy between PEMs and other components in PEMFCs.Future research should focus on the performance of PEMs in the actual operating environment of PEMFCs.
作者 梁铣 吴亮 杨正金 徐铜文 Xian Liang;Liang Wu;Zhengjin Yang;Tongwen Xu(CAS Key Laboratory of Soft Matter Chemistry,Collaborative Innovation Centre of Chemistry for Energy Materials,School of Chemistry and Materials Science,University of Science and Technology of China,Hefei 230026,China;School of Chemistry and Materials Engineering,Huainan Normal University,Huainan 232038,China)
出处 《科学通报》 EI CAS CSCD 北大核心 2022年第19期2226-2240,共15页 Chinese Science Bulletin
基金 国家重点研发计划(2020YFB1505601,2018YFB1502301) 安徽省自然科学基金(2008085QB95)资助。
关键词 聚电解质燃料电池 质子交换膜 主链 侧链 结构优化 polyelectrolyte fuel cells proton exchange membrane main chain side chain structure optimization
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