Molecular crowding electrolytes for stabilizing Zn metal anode in rechargeable aqueous batteries

A solid electrolyte interphase (SEI) with a robust mechanical property and a high ionic conductivity is imperative for high-performance zinc metal batteries. However, it is difficult to form such a SEI directly from an electrolyte. In this work, a molecular crowding effect is based on the introduction of Zn(OTF)2 and Zn(ClO4)2 to 2 mol/L ZnSO4 electrolytes. Simulations and experiments indicate that the Zn(OTF)2 and Zn(ClO4)2 not only create a molecularly crowded electrolyte environment to promote the interaction of Zn2+and OTF−, but also participate in the reduction to construct a robust and high ionic-conductive SEI, thus promoting metal zinc deposition to the (002) crystal surface. With this molecular crowding electrolyte, a high current density of 1 mA/cm2 can be obtained by assembling symmetric batteries with Zn as the anode for over 1000 h. And in a temperature environment of −10 °C, a current density of 1 mA/cm2 can be obtained by assembling symmetric batteries with Zn for over 200 h. Zn//Bi2S3/VS4@C cells achieve a CE rate of up to 99.81% over 1000 cycles. Hence, the utilization of a molecular crowding electrolyte is deemed a highly effective approach to fabricating a sophisticated SEI for a zinc anode. The schematic diagrams for molecular crowding effect. Due to the uneven deposition of ZnSO4 electrolyte, resulting in corrosion and hydrogen evolution reactions, and the dendrite growth and by-products are formed. Due to the molecular crowding effect, SEI layer containing ZnF2 can be generated on Zn anode, and the electric field direction is consistent, which is conducive to the deposition of (002) crystal surface, reducing the formation of by-products and dendrite growth. [Display omitted]