Data-Assisted Design of Temperature-Resistant Weakly Solvating Electrolyte for All-Climate 500 Wh/kg Lithium-Metal Batteries
Zhongzhe Li, Weiyu Wang, W. Zhang, Yufang Chen, Xiaoru Yun, Tao Teng, Chunman Zheng, Ligang Xu, Mingxue Tang, Yun Zhao, Baohua Li, Jilei Liu, Peitao Xiao
Abstract
Temperature-resistant weakly solvating electrolytes (TRWSEs) are indispensable for lithium-metal batteries with ultrahigh energy density (≥450 Wh kg –1 ) and excellent temperature adaptability (±70 °C). However, how to design ideal TRWSEs efficiently and decipher their evolution at different temperatures is still a great challenge. Herein, via a data-driven strategy, a TRWSE with a melting point as low as −136 °C was elaborately designed. More importantly, the evolution of the TRWSE from intrinsic solvation structures to interphase constructions and to lithium-metal deposition at different temperatures was investigated. Intriguingly, the anion-rich solvation structures in this TRWSE, the anion-derived electrolyte–electrode interphases, and deposited lithium are all temperature-insensitive, especially at low temperatures. Consequently, lithium dendrites are effectively suppressed even at −30 °C with a high Coulombic efficiency of 98.2%. NCM811||Li cells exhibit highly enhanced cycling stability with a capacity retention of almost 100% after 300 cycles at −30 °C. Moreover, 8.5 Ah pouch cells, with a high energy density of 507 Wh kg –1 and an ultrawide operating temperature of 140 °C, still deliver a capacity retention of 92.3% at temperatures as low as −70 °C, which can discharge even at −110 °C, demonstrating their huge potential at ultralow temperatures.