Qing Xuan Shi scite author profile

Recently, stringent requirements brought on by environmental regulations and safety issues are driving the development of solid electrolytes to replace conventional liquid electrolyte systems for lithium‐based secondary batteries (LiBs). However, the low Li‐ion conductivity and/or poor mechanical properties of electrolytes remain the main obstacles hindering their commercialization. Hierarchitectural and composite polymer separators (CPSs) based on electrolyte membranes have been reported as promising tools for both high ionic conductivity and mechanical stability. In light of such work, the new types of flexible electrolytes based on phase‐separated and mixed‐phase morphologies achieved via self‐assembly and the use of functional molecular composites are reviewed along with the fundamental mechanisms associated with such systems. In particular, the structure and morphology, ionic conductivity, thermal/mechanical stability, and fabrication of polymer electrolytes are introduced. Additionally, recent advancements in CPSs including methods of ensuring low interfacial resistance, the respective contributions of these critical factors to the significant functional properties of CPSs, and directions for development and essential applications in the field of CPSs for LiBs are presented. Based on previous works, the perspectives put forth will aid in the design of advanced electrolytes for practical Li secondary batteries in the near future.

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UV-curable boron nitride nanosheet/ionic liquid-based crosslinked composite polymer electrolyte in lithium metal batteries

Xia

Shi

et al. 2019

Journal of Power Sources

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Mesoporous silica nanoplates facilitating fast Li⁺ diffusion as effective polysulfide-trapping materials for lithium–sulfur batteries

Xiao

Shi

et al. 2019

J. Mater. Chem. A

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Qing Xuan Shi

Large-scaled covalent triazine framework modified separator as efficient inhibit polysulfide shuttling in Li-S batteries

Constructing desirable ion-conducting channels within ionic liquid-based composite polymer electrolytes by using polymeric ionic liquid-functionalized 2D mesoporous silica nanoplates

Tough and Flexible, Super Ion‐Conductive Electrolyte Membranes for Lithium‐Based Secondary Battery Applications

UV-curable boron nitride nanosheet/ionic liquid-based crosslinked composite polymer electrolyte in lithium metal batteries

Mesoporous silica nanoplates facilitating fast Li⁺ diffusion as effective polysulfide-trapping materials for lithium–sulfur batteries

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Qing Xuan Shi

Large-scaled covalent triazine framework modified separator as efficient inhibit polysulfide shuttling in Li-S batteries

Constructing desirable ion-conducting channels within ionic liquid-based composite polymer electrolytes by using polymeric ionic liquid-functionalized 2D mesoporous silica nanoplates

Tough and Flexible, Super Ion‐Conductive Electrolyte Membranes for Lithium‐Based Secondary Battery Applications

UV-curable boron nitride nanosheet/ionic liquid-based crosslinked composite polymer electrolyte in lithium metal batteries

Mesoporous silica nanoplates facilitating fast Li+ diffusion as effective polysulfide-trapping materials for lithium–sulfur batteries

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Mesoporous silica nanoplates facilitating fast Li⁺ diffusion as effective polysulfide-trapping materials for lithium–sulfur batteries