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Molecularly engineered linear organic carbonates as practically viable nonflammable electrolytes for safe Li-ion batteries

Title
Molecularly engineered linear organic carbonates as practically viable nonflammable electrolytes for safe Li-ion batteries
Author(s)
Lee, JinaJeon, A-ReLee, Hye JinShin, UkseonYoo, YiseulLim, Hee-DaeHan, CheolheeLee, HochunKim, Yong JinBaek, JayeonSeo, Dong-HwaLee, Minah
Issued Date
2023-07
Citation
Energy & Environmental Science, v.16, no.7, pp.2924 - 2933
Type
Article
Keywords
FLASH-POINTSTABILITYMECHANISMGRAPHITECELLSLITHIUM-IONETHYLENE-CARBONATETHERMAL RUNAWAY
ISSN
1754-5692
Abstract
Fire and explosion hazards represent a major barrier to the widespread adoption of lithium-ion batteries (LIBs) in electric vehicles and energy storage systems. Although mitigating the flammability of linear organic carbonate electrolytes in LIBs is an obvious solution to the thermal safety issue, it often comes at the expense of battery performance and cost. Herein, by combining alkyl-chain extension and alkoxy substitution, which simultaneously decreases solvent volatility and increases solvation ability, we demonstrate that molecular engineering of the linear carbonates presents a viable route to achieving thermally stable high-performance batteries. Although the tailored molecule bis(2-methoxyethyl) carbonate (BMEC) exhibits a flash point that is 90 °C higher than that of conventional electrolytes, the electrolyte quality is still maintained, enabling long-lasting cycling of the flagship electrode combination of graphite and Ni-rich layered oxide over 500 cycles in practical pouch cells. Furthermore, unlike a commercial electrolyte, we demonstrate that the BMEC electrolyte effectively alleviates heat and reactive-gas release under thermal/mechanical/electrical abuse conditions in the presence of charged electrodes, thereby preventing the thermal explosion of a 4 A h pouch cell upon nail penetration.
URI
http://hdl.handle.net/20.500.11750/45896
DOI
10.1039/d3ee00157a
Publisher
Royal Society of Chemistry
Related Researcher
  • 이호춘 Lee, Hochun
  • Research Interests Lithium-ion batteries; Novel Materials for rechargeable batteries; Novel energy conversion;storage systems; Electrochemistry; 리튬이차전지; 이차전지용 신규 전극 및 전해액; 신규 에너지변환 및 저장 시스템; 전기화학
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Department of Energy Science and Engineering Electrochemistry Laboratory for Sustainable Energy(ELSE) 1. Journal Articles

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