Abstract
Reversibility and anode utilization remain key barriers to realizing practical, rechargeable Zn metal batteries. Herein, we report a heteroatomic molecule, 3,5-bis(trifluoromethyl)pyrazole (TFMP), capable of promoting a fluorinated and polymeric interphase in every class of zinc electrolyte (acidic, alkaline, non-aqueous). Significant improvements in performance are observed in TFMP-based electrolytes including coulombic efficiencies exceeding 99% and utilizations up to 80%. Notably, dendrite formation is effectively suppressed in all classes of electrolytes with the most impressive performance observed in weakly acidic aqueous media with selective entrainers. In full cells constructed with a thin (10-mu m) Zn anode and an organic cathode, excellent performance is demonstrated with an exceptionally low n/p ratio (5.4) and high energy density (270 W h L-1, projected for 18 650 cell) in aqueous media. This work highlights that interphasial chemistries originating from additive-level electrolyte components can manifest major improvements without significantly altering the composition, cost, and key properties of traditional zinc electrolytes that were already optimized.
By employing 3,5-bis(trifluoromethyl) pyrazole (TFMP) as an electrolyte additive in both aqueous and non-aqueous mediums, a versatile interphase strategy is achieved. This facilitates stable Zn anodes with improved efficiency and longer cycling life.