In situ construction of anti-corrosion structure via intermediate carbon cloth for long-life zinc anode

Metallic zinc is regarded as an ideal anode in aqueous batteries, while the poor life associated with the ever -deepening interface corrosion and dendrite growth severely restricts the practical application. Herein, in situ construction of anti-corrosion structure via intermediate carbon cloth is developed to realize stable Zn deposition for long-life utilization. During the repeated charge and discharge, anode reactions including Zn plating and the parasitic reactions are gradually transferred to the intermediate carbon surface, and the growth of byproduct (zinc hydroxide sulfate, also ZHS) is regulated as a lateral pattern. This stable interface growth activates the stabilizing effect from ZHS and makes it an anti-corrosion structure for further Zn deposition. Meanwhile, such a layer also effectively adsorbs Zn atoms for the uniform nucleation and growth. As a result, over 3200 h of stable Zn plating/stripping is realized at a practical current density of 1 mA cm-2, and both the reaction current and the capacity can be stably extended to 10 mA cm-2 and 10 mAh cm-2. This work redefines the stabilizing effect of conductive interphase layer, and provides a new insight into the growth regulation of ZHS byproduct and the self anti-corrosion effect.

Automated summary

In situ construction of an anti-corrosion structure via intermediate carbon cloth enables stable zinc deposition and extends battery life. The intermediate carbon cloth regulates the growth of the zinc hydroxide sulfate (ZHS) byproduct, activating its stabilizing effect and forming an anti-corrosion structure for further zinc deposition. Additionally, the carbon cloth effectively adsorbs zinc atoms, facilitating uniform nucleation and growth. Experimental results demonstrate over 3200 hours of stable zinc plating/stripping at a practical current density, with stable extension of reaction current and capacity.