Stabilizing Zn Metal Anodes via Cation/Anion Regulation toward High Energy Density Zn-Ion Batteries

Aqueous zinc batteries (AZBs) are promising energy storage devices owing to their high safety, low cost, and environmental friendliness. However, energy density improvement and lifespan prolongation of AZBs are impeded by the poor reversibility of Zn anodes. Instead of focusing on restraining the water activity that has been widely discussed, this work reports a unique strategy to eliminate the side reactions, which is the simultaneous regulation of cation and anion fluxes by microporous material. The as-synthesized protective layer possesses an excellent sieving ability to repel sulfate infiltration by channel effect and via the electric field, and homogenizes Zn ion flux to achieve a dendrite-free morphology, which is confirmed by the electrochemical and theoretical investigations. The protected anode exhibits a long lifespan (2400 h), deep Zn plating/stripping, and high current tolerance (100 mA cm(-2)). As a result, the full battery achieves a capacity retention of 76.4% after 7500 cycles, and in the anode-free configuration, a high energy density of 192.8 Wh kg(-1) is observed, which is more than 50 times that of a full battery with a Zn foil anode. By regulating the cations and anions simultaneously, the proposed strategy provides a low-cost remedy to achieve the practical scale-up of AZBs.

Automated summary

This study reports a unique strategy to improve the energy density and lifespan of AZBs by simultaneously regulating cation and anion fluxes using a microporous material. The as-synthesized protective layer effectively repels sulfate infiltration and homogenizes Zn ion flux, achieving a dendrite-free morphology. The protected anode exhibits a long lifespan, deep Zn plating/stripping, and high current tolerance, providing a low-cost remedy for practical scale-up of AZBs.