Decoding the Mechanisms of Reversibility Loss in Rechargeable Zinc-Air Batteries

TL;DR

This paper investigates the mechanisms behind reversibility loss in rechargeable zinc-air batteries, revealing how morphological changes and hydrogen evolution cause capacity fade, and proposes a new cycling protocol to improve battery lifespan.

Contribution

It uncovers the detailed mechanisms of reversibility loss in RZABs and introduces a novel overcharge-cycling protocol to mitigate capacity degradation.

Findings

Mossy zinc morphology dominates in later cycling stages.

Hydrogen evolution induces zincate concentration increase and oxide passivation.

The proposed protocol significantly extends battery lifespan.

Abstract

Attaining high reversibility of electrodes and electrolyte is essential for the longevity of secondary batteries. Rechargeable zinc-air batteries (RZABs), however, encounter drastic irreversible changes in the zinc anodes and air cathodes during cycling. To uncover the mechanisms of reversibility loss in RZABs, we investigate the evolution of zinc anode, alkaline electrolyte, and air electrode through experiments and first-principles calculations. Morphology diagrams of zinc anodes under versatile operating conditions reveal that the nano-sized mossy zinc dominates the later cycling stage. Such anodic change is induced by the increased zincate concentration due to hydrogen evolution, which is catalyzed by the mossy structure and results in oxide passivation on electrodes, and eventually leads to low true Coulombic efficiencies and short lifespans of batteries. Inspired by these findings, we finally present a novel overcharge-cycling protocol to compensate the Coulombic efficiency loss caused by hydrogen evolution and significantly extend the battery life.