Abstract
All solid-state lithium-ion batteries based on polymer electrolytes have higher safety and energy density, but the low conductivity of lithium ion restricts its application. This study proposes a new method to promote the ionic conductivity of polyethylene oxide (PEO)-based solid electrolytes. In this method, the PEO-based solid electrolyte was first prepared by casting, and then power ultrasound was exerted on the electrolyte by a sandwich structure to modify the electrolyte structure. Through analysis of the performance and microstructure of the electrolyte, it was found that the ultrasonic treatment increased the ionic conductivity by 78%, improved tensile strength and plastic deformation ability, but did not affect the thermal stability and the chemical composition. The ultrasonic vibration, exerting high energy to the solid electrolyte through high-frequency vibration, broke PEO grains and melted them with the frictional heat at boundary. Due to the slight melting and fast solidifying produced by the pulsed ultrasonic treatment, the crystallization was suppressed. The crystallinity was thus reduced by 6.2%, which increased the migration channels of lithium ions and reduced the tortuosity effect. Furthermore, the ultrasonic vibration compressed the electrolyte to produce plastic flow of the material, which made the electrolyte structure more compact. The density of ethylene oxide (EO) units thus increased in the amorphous phase, providing multiple electron-donor coordination sites for the Li+. The hopping distance of the ion between donors decreased, which also facilitated the migration. In addition, the mechanical performance of the electrolyte membrane improved. This study provides a reference for the improvement of polymer based all-solid-state batteries.
Highlights
In recent years, with the advancement of new energy vehicles, the market has put forward new requirements for batteries
Lithium ion transport in a polyethylene oxide (PEO)-based solid electrolyte is derived from segmental movement that can be accelerated in the amorphous PEO compared with that in the crystalline PEO [8]
The ultrasonic vibration method was used to improve the performance of the PEO-based solid electrolyte
Summary
With the advancement of new energy vehicles, the market has put forward new requirements for batteries. Kumar et al [10] added 1-Ethyl-3-methy limidazolium trifluoromethane-sulfonate (EMITF) ionic liquid to the PEO-based electrolyte system, and found that the organic cation EMI+ can interact with the PEO segment, increase the amorphous phase ratio, and improve the lithium ion transport capacity. Xiao-Yuan Yu et al [14] prepared a new type of PEO/poly propylene carbonate (PPC) solid electrolyte by blending PEO with poly propylene carbonate (PPC), and found that the addition of PPC can effectively reduce the glass transition temperature Tg and crystallinity of the PEO and improve the ionic conductivity of the electrolyte. Applied a block copolymer consisting of PEO and polystyrene (PS) to prepare a LiClO4 -contained solid polymer electrolyte with high ionic conductivity at room temperature. If the polymer electrolyte is subjected to ultrasound, high-frequency vibration breaks the electrolyte grains, increasing the ratio of the amorphous phase, and thereby improves the lithium ion conductivity.
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