LAUSR

Abstract Rechargeable lithium-based battery is hailed as next-generation high-energy-density battery systems. However, growth of lithium dendrites, shuttle effect of lithium polysulfides intermediates and unstable interphase of high-voltage intercalation-type cathodes largely prevent their practical deployment. Herein, to fully conquer the three challenges via one strategy, a novel electrolyte with highly-coordinated solvation structure-in-nonsolvent is designed. On account of the particular electrolyte structure, the shuttle effect is completely suppressed by quasi-solid conversion of S species in Li-S batteries, with a stable cycle performance even at lean electrolyte (5 μL mg−1). Simultaneously, in-situ-formed highly-fluorinated interphases can not only lower Li+ diffusion barrier to ensure uniform nucleation of Li but also improve stability of NCM cathodes, which enable excellent capacity retention of Li||LiNi0.5Co0.2Mn0.3O2 batteries under conditions toward practical applications (high loading of 2.7 mAh cm−2 and lean electrolyte of 5 mL Ah−1). Besides, the electrolyte is also nonflammable. This electrolyte structure offers useful guidelines for the design of novel organic electrolytes for practical lithium-based batteries.