Synergistic Regulation of Electrolyte Composition and Electrode Interface for Enhanced Low-Temperature Performance of Lithium-Ion Batteries

电解质 材料科学 电池(电) 电极 化学工程 溶剂化 钝化 纳米技术 容量损失 法拉第效率 溶剂 相间 碳酸盐 介电谱 稀释剂 堆积 超级电容器 磷酸三甲酯 接口(物质)
作者
Yue Wang,Baodi Lu,Liang Ming,Mingwei Ouyang,Yutong Tan,Ge Wen
出处
期刊:ACS applied energy materials [American Chemical Society]
标识
DOI:10.1021/acsaem.6c00091
摘要

Lithium-ion batteries hold enormous potential for applications in diverse fields, including electric vehicles, aerospace engineering, and 3C consumer electronics. However, their practical deployment is limited by a narrow operating temperature range. To address this challenge, we develop a systematic strategy focusing on both electrolyte engineering and interface modification for improved low-temperature conditions. Our electrolyte design employs methyl propionate as the primary solvent due to its low freezing point, complemented by fluoroethylene carbonate (FEC) as a film-forming additive and bis(2,2,2-trifluoroethyl) ether (BTFE) as the diluent to regulate the Li+ solvation structure. This synergistic formation enables the formation of a passivation layer (e.g., LiF and Li2CO3) on the electrode surface, which effectively reduces the low-temperature interface impedance and enhances charge transfer. Through the synergistic effects of FEC and BTFE, the optimized electrolyte exhibits considerable cycling performance at room temperature in both NCM523||Li and graphite||Li half-cells. Furthermore, the NCM523||graphite full cell delivers satisfactory cycling performance at both RT and –20 °C. Notably, it retains approximately 60% of its RT capacity (90.5 mAh g−1 even at –40 °C and 0.1 C)), which is supported by the high discharge capacities of 104.5 and 245.2 mAh g−1 from NCM523/Li and graphite/Li half cells, respectively, under the same extreme conditions. In summary, this study demonstrates a rationally designed electrolyte system that synergistically enhances the low-temperature performance and cycling stability of LIBs through tailored solvation structure and robust interphase engineering, offering a viable pathway for their application in extreme environments.
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