Journal
ADVANCED FUNCTIONAL MATERIALS
Volume 32, Issue 14, Pages -Publisher
WILEY-V C H VERLAG GMBH
DOI: 10.1002/adfm.202110653
Keywords
ionic conductivity; ionic liquids; lithium-metal batteries; ionogels; solid-state electrolytes
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Funding
- National Natural Science Foundation of China [51972132, 51772116, 52002141]
- Program for HUST Academic Frontier Youth Team [2016QYTD04]
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The study demonstrates a novel ionogel electrolyte membrane with high Li+ conductivity and excellent thermal stability, utilizing positively charged poly(ionic liquid) nanofibers favorable for Li+ transport, improving the rate capability and cyclability of solid-state lithium batteries over a wider temperature range.
Monolithic ionogel electrolyte membranes (IGEMs) based on gelling scaffolds and ionic liquids have aroused intensive interest because of their broad processing compatibility, nonflammability, and favorable thermal and electrochemical features. However, the absence of functional scaffolds that concurrently enable high mechanical strength and Li+ transportability of IGEMs constrains the battery power and safety. Herein, a task-specific IGEM monolith featuring high Li+ conductivity and outstanding thermal stability is demonstrated, whereby electrospun positively charged poly(ionic liquid) nanofibers serve as a thermotolerant scaffold for the IGEM. Regulating the Li+ environment in the IGEM enables the shift from the sluggish vehicular to fast structural Li-ion transport mode. With the unique IGEM, the solid-state Li||LiFePO4 cells achieve improved rate capability and good cyclability in a wide temperature range from 0 to 90 degrees C. Furthermore, practical solid-state Li||LiFePO4 pouch cells with a cathode capacity of approximate to 2 mAh cm(-2) have also been demonstrated.
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