4.8 Article

High-Performance Quasi-Solid-State Pouch Cells Enabled by in situ Solidification of a Novel Polymer Electrolyte

Journal

ENERGY & ENVIRONMENTAL MATERIALS
Volume 6, Issue 4, Pages -

Publisher

WILEY
DOI: 10.1002/eem2.12447

Keywords

high areal capacity; high-energy-density pouch cells; in situ solidification; poly(ethylene glycol) diacrylate-based polymer electrolyte

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Conventional lithium-ion batteries (LIBs) with liquid electrolytes have safety concerns in electric vehicles. All-solid-state batteries with solid-state electrolytes have been proposed, but face challenges of poor solid-solid contact and fast interface degradation. In this work, quasi-solid-state pouch cells were fabricated via in situ solidification of polymer electrolytes, showing stable electrochemical performance over 500 cycles. The excellent stability is attributed to the formation of a robust and compatible interphase, inhibiting interfacial side reactions and structural degradation. This work demonstrates the facile and cost-effective approach of in situ solidification for quasi-solid-state pouch cells with high performance and safety.
Conventional lithium-ion batteries (LIBs) with liquid electrolytes are challenged by their big safety concerns, particularly used in electric vehicles. All-solid-state batteries using solid-state electrolytes have been proposed to significantly improve safety yet are impeded by poor interfacial solid-solid contact and fast interface degradation. As a compromising strategy, in situ solidification has been proposed in recent years to fabricate quasi-solid-state batteries, which have great advantages in constructing intimate interfaces and cost-effective mass manufacturing. In this work, quasi-solid-state pouch cells with high loading electrodes (>= 3 mAh cm(-2)) were fabricated via in situ solidification of poly(ethylene glycol)diacrylate-based polymer electrolytes (PEGDA-PEs). Both single-layer and multilayer quasi-solid-state pouch cells (2.0 Ah) have demonstrated stable electrochemical performance over 500 cycles. The superb electrochemical stability is closely related to the formation of robust and compatible interphase, which successfully inhibits interfacial side reactions and prevents interfacial structural degradation. This work demonstrates that in situ solidification is a facile and cost-effective approach to fabricate quasi-solid-state pouch cells with both excellent electrochemical performance and safety.

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