Separators or electrolyte membranes are recognized as the key components to guarantee ion transport in rechargeable batteries.However,the ever-growing applications of the battery systems for diverse working environmen...Separators or electrolyte membranes are recognized as the key components to guarantee ion transport in rechargeable batteries.However,the ever-growing applications of the battery systems for diverse working environments bring new challenges,which require advanced battery membranes with high thermal stability,excellent mechanical strength,high voltage tolerance,etc.Therefore,it is highly desirable to design novel methods/concepts to solve the current challenges for battery membranes through understanding the mechanism of novel phenomena and electrochemical reactions in battery systems working under unconventional conditions.Recently,the new emerging Janus separators or electrolyte membranes with two or more distinct chemical/physical properties arising from their asymmetric structure and composition,are promising to address the above challenges via rational design of their targeted functionalities.To this end,in this review,we first briefly cover the current challenges of the traditional battery membrane for battery devices working in unconventional conditions.Then,the state-of-art developments of the rational design of Janus membranes to overcome the above challenges for diverse battery applications are summarized.Finally,we outline these latest developments,challenges,and future potential directions of the Janus membrane.Our review is aimed to provide basic guidance for developing functional separators or electrolyte membranes for advanced batteries.展开更多
由于锌金属在电解液中热力学不稳定而自发地发生寄生反应(析氢、枝晶生长等),水系锌离子电池的商业化应用受到了阻碍.因此,我们构建了一种高粘附性的锌离子传导聚合物聚乙烯醇缩甲醛(PVF)缓冲层,来抑制这些寄生反应的发生,从而提高锌沉...由于锌金属在电解液中热力学不稳定而自发地发生寄生反应(析氢、枝晶生长等),水系锌离子电池的商业化应用受到了阻碍.因此,我们构建了一种高粘附性的锌离子传导聚合物聚乙烯醇缩甲醛(PVF)缓冲层,来抑制这些寄生反应的发生,从而提高锌沉积的可逆性.这种致密的人工缓冲层不仅能有效隔绝电解质与锌负极之间的直接接触,还能适应锌沉积/剥离过程中的体积膨胀,并引导锌成核过程.具体来说,PVF层可提高成核过电位,并促进Zn2+的三维扩散过程,使PVF层下的Zn2+沉积通量均匀化.我们设计的PVF@Zn具有高循环稳定性和不易生成枝晶的特点,基于该电极的对称电池的长循环寿命超过5200 h,比Zn负极电池提高了近35倍,甚至可以在40.0 mA cm^(−2)的超高电流密度下稳定运行.此外,PVF@Zn||NVO全电池在1.0 A g^(−1)的条件下进行2400个循环后,仍能保持172.4 mA h g^(−1)的比容量.这种通过消除自发寄生反应并调节锌均匀沉积及成核的策略,为设计实用化高性能锌负极提供了重要借鉴.展开更多
基金supported by the Science and Technology Development Fund from Macao SAR(FDCT-0057/2019/A1,0092/2019/A2,and 0035/2019/AMJ)Startup grants(SRG2018-00140-IAPME)from the Research and Development Office at University of Macao+1 种基金National Natural Science Foundation of China(Grant no.21875040 and 21905051)Chongqing Key Laboratory fund of Soft-Matter Material Chemistry and Function Manufacturing(No.20200003).
文摘Separators or electrolyte membranes are recognized as the key components to guarantee ion transport in rechargeable batteries.However,the ever-growing applications of the battery systems for diverse working environments bring new challenges,which require advanced battery membranes with high thermal stability,excellent mechanical strength,high voltage tolerance,etc.Therefore,it is highly desirable to design novel methods/concepts to solve the current challenges for battery membranes through understanding the mechanism of novel phenomena and electrochemical reactions in battery systems working under unconventional conditions.Recently,the new emerging Janus separators or electrolyte membranes with two or more distinct chemical/physical properties arising from their asymmetric structure and composition,are promising to address the above challenges via rational design of their targeted functionalities.To this end,in this review,we first briefly cover the current challenges of the traditional battery membrane for battery devices working in unconventional conditions.Then,the state-of-art developments of the rational design of Janus membranes to overcome the above challenges for diverse battery applications are summarized.Finally,we outline these latest developments,challenges,and future potential directions of the Janus membrane.Our review is aimed to provide basic guidance for developing functional separators or electrolyte membranes for advanced batteries.
基金supported by the Platform Supporting Fund of Qingyuan Innovation Laboratory(00623001)the Key Program of Qingyuan Innovation Laboratory(00223002).
文摘由于锌金属在电解液中热力学不稳定而自发地发生寄生反应(析氢、枝晶生长等),水系锌离子电池的商业化应用受到了阻碍.因此,我们构建了一种高粘附性的锌离子传导聚合物聚乙烯醇缩甲醛(PVF)缓冲层,来抑制这些寄生反应的发生,从而提高锌沉积的可逆性.这种致密的人工缓冲层不仅能有效隔绝电解质与锌负极之间的直接接触,还能适应锌沉积/剥离过程中的体积膨胀,并引导锌成核过程.具体来说,PVF层可提高成核过电位,并促进Zn2+的三维扩散过程,使PVF层下的Zn2+沉积通量均匀化.我们设计的PVF@Zn具有高循环稳定性和不易生成枝晶的特点,基于该电极的对称电池的长循环寿命超过5200 h,比Zn负极电池提高了近35倍,甚至可以在40.0 mA cm^(−2)的超高电流密度下稳定运行.此外,PVF@Zn||NVO全电池在1.0 A g^(−1)的条件下进行2400个循环后,仍能保持172.4 mA h g^(−1)的比容量.这种通过消除自发寄生反应并调节锌均匀沉积及成核的策略,为设计实用化高性能锌负极提供了重要借鉴.
