Tailoring terminal groups in sulfonyl solvents to boost compatibility with lithium metal anodes.
Jinmin Wang, Shuang Wei, Mingming Fang, Angye Li, Qian Zheng, Xubing Dong, Yuanmao Chen, Kang Yuan, Xinyang Yue, Zheng Liang
Abstract
Open AccessSulfonyl-based compounds are considered promising electrolyte solvents because of their high dielectric constant, excellent anodic stability, and non-flammability. However, their use in Li metal batteries (LMBs) is limited by their incompatibility with Li, causing unstable interfacial chemistry and dendrite growth. Herein, we designed an N,N-dimethylsulfamoyl fluoride (DMSF) electrolyte by functionalizing a fluorosulfonyl (FSO2 -) core with an N,N-dimethyl terminal group, enabling the LMB with enhanced cycling stability and energy density. The increased steric hindrance in DMSF with methylation weakens the interaction with Li ions, resulting in a structure that is weakly solvating and exhibits fast ion transport kinetics. Methylation also facilitates the decomposition of DMSF, leading to the formation of a rich LiF/Li2S hybrid solid electrolyte interphase that suppresses interfacial side reactions. Consequently, the 4.5 V-charged 50 µm Li‖LiNi0.8Co0.1Mn0.1O2 (4 mAh cm-2) cells exhibit stable cycling (80% capacity retention for 850 cycles), 5C fast charging, and a wide operating temperature range (-50-60 °C). Moreover, a 5-Ah pouch cell employing DMSF delivers an energy density of 540 Wh kg-1 and exhibits high stability over 110 cycles. This study establishes terminal group modification as a crucial advance for developing compatible sulfonyl-based electrolytes in high-performance LMBs.