AI Article Synopsis
- Extensively-used lithium-ion batteries struggle with safety and lifespan issues.
- A new ultrathin solid polymer electrolyte is created by combining ionic liquid, polyurethane, and lithium salt to improve performance.
- This innovation enhances thermal conductivity by reducing phonon scattering, significantly increasing safety by preventing thermal runaway in batteries.
Article Abstract
Extensively-used rechargeable lithium-ion batteries (LIBs) face challenges in achieving high safety and long cycle life. To address such challenges, ultrathin solid polymer electrolyte (SPE) is fabricated with reduced phonon scattering by depositing the composites of ionic-liquid (1-ethyl-3-methylimidazolium dicyamide, EMIM:DCA), polyurethane (PU) and lithium salt on the polyethylene separator. The robust and flexible separator matrix not only reduces the electrolyte thickness and improves the mobility of Li, but more importantly provides a relatively regular thermal diffusion channel for SPE and reduces the external phonon scattering. Moreover, the introduction of EMIM:DCA successfully breaks the random intermolecular attraction of the PU polymer chain and significantly decreases phonon scattering to enhance the internal thermal conductivity of the polymer. Thus, the thermal conductivity of the as-obtained SPE increases by approximately six times, and the thermal runaway (TR) of the battery is effectively inhibited. This work demonstrates that optimizing thermal safety of the battery by phonon engineering sheds a new light on the design principle for high-safety Li-ion batteries.
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| http://dx.doi.org/10.1002/adma.202405097 | DOI Listing |
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