Controlling Fluoride-Forming Reactions for Improved Rate Capability in Lithium-Perfluorinated Gas Conversion Batteries

Nonaqueous metal-gas batteries based on halogenated reactants exhibit strong potential for future high-energy electrochemical systems. The lithium-sulfur hexafluoride (Li-SF6) primary battery, which utilizes a safe, noncombustible, energy-dense gas as cathode, demonstrates attractive eight-electron transfer reduction during discharge and high attainable capacities (>3000 mAh g(carbon)(-1)) at voltages above 2.2 V-Li. However, improved rate capability is needed for practical applications. Here, two viable strategies are reported to achieve this by targeting the solubility of the passivating discharge product, lithium fluoride (LiF). Operating at moderately elevated temperatures, e.g., 50 degrees C, in DMSO dramatically improves LiF solubility and promotes sparser and larger LiF nuclei on gas diffusion layer electrodes, leading to capacity improvements of approximate to 10x at 120 mu A cm(-2). More aggressive chemical modification of the electrolyte by including a tris(pentafluorophenyl)borane anion receptor further promotes LiF solubilization; capacity increases even at room temperature by a factor of 25 at 120 mu A cm(-2), with attainable capacities up to 3 mAh cm(-2). This work shows that bulk fluoride-forming conversion reactions can be strongly manipulated by tuning the electrolyte environment to be solvating toward F-, and that significantly improved rates can be achieved, leading a step closer to practical applications.