PNNL

Abstract

Electrolytes not only dictates the device performance, but also the major part of VRFB system cost, making it as main focus of extensive research efforts in this field. Most research efforts directed towards finding an optimal supporting electrolyte and/or additive materials, which can increase the vanadium cations solubility and stability. Current research efforts were mostly trial and error methods, yielding marginal improvements in chemical/thermal stability while potentially compromising on other functional properties such as conductivity and viscosity. In addition, any supporting electrolyte and/or additives used to enhance vanadium solubility or cell potential will eventually diffuse across the membrane making it necessary to be compatible with both half-cell reactions to ensure long battery life. Another aspect of ensuring longer battery life cycle with minimum self-discharge of VRFB would be the additive/supporting electrolyte should exhibit prolonged thermal and chemical stability, typically over 30 days at battery operating temperature of -5 to 50 C. These practical requirements may limit the implementation of many additives currently under investigation. Despite extensive research, identifying the optimal material for stabilizing the vanadium electrolyte has been rather slow owing to the widely used empirical approach.