Liuxue Shen

Development of sulfur cathodes with 100% coulombic efficiency (CE) and good cycle stability remains challenging due to the polysulfide dissolution in electrolytes. Here, it is demonstrated that electrochemical reduction of lithium bis(fluorosulfonyl)imide (LiFSI) based electrolytes at a potential close to the sulfur cathode operation forms in situ protective coating on both cathode and anode surfaces. Quantum chemistry studies suggest the coating formation is initiated by the FSI(-F) anion radicals generated during electrolyte reduction. Such a reduction additionally results in the formation of LiF. Accelerated cycle stability tests at 60 °C in a very simple electrolyte (LiFSI in dimethoxyethane with no additives) show an average CE approaching 100.0% over 1000 cycles with a capacity decay less than 0.013% per cycle after stabilization. Such a remarkable performance suggests a great promise of both an in situ formation of protective solid electrolyte coatings to avoid unwanted side reactions and the use of a LiFSI salt for this purpose.

Electrochemical reduction of lithium bis(fluorosulfonyl)imide-based electrolytes allows in situ formation of efficient protective coatings on the surface of both electrodes, which dramatically improve Li/S cell coulombic efficiency and cycle stability. Quantum chemistry studies suggest the coating formation is initiated by the FSI(F) anion radicals generated during electrolyte reduction. Such a reduction additionally results in the formation of LiF.