Decoupling, quantifying, and restoring aging-induced Zn-anode losses in rechargeable aqueous zinc batteries

Rechargeable aqueous zinc batteries offer low cost, safety, and good cycling capacity, largely due to the water-compatible Zn-metal anode. However, Zn anodes corrode in aqueous electrolytes. While such corrosion is well known, distinguishing the relative importance of corrosion contributions toward anode capacity loss remains less understood. Here, by systematically cycling Zn anodes with controlled loading and under different aging conditions, we suc-cessfully decouple and quantify the aging-induced contributions to-ward anode degradation in mildly acidic aqueous electrolytes. While some losses occur due to the irreversible consumption of Zn into corrosion by-products, we demonstrate that the bigger contributor to this efficiency loss (over 80%) is the physical screening effect of evolved gases, preventing the reversible dissolution of deposited Zn. Understanding the crucial role of evolved gas during cell aging, and how it can accumulate and effectively passivate large sections of the battery anode, will have important implications in the develop-ment of rechargeable aqueous zinc batteries.

Automated summary

Rechargeable aqueous zinc batteries offer low cost, safety, and good cycling capacity, largely due to the water-compatible Zn-metal anode. However, Zn anodes corrode in aqueous electrolytes. This study successfully decouples and quantifies the aging-induced contributions toward anode degradation in mildly acidic aqueous electrolytes, demonstrating that the physical screening effect of evolved gases is the bigger contributor to the efficiency loss of these batteries.