Quantifying Silver Dissolution in Primary and Secondary AgO-Zn Batteries

Printable AgO-Zn batteries are highly attractive for wearable devices for their safe chemistry, high energy density, and rechargeability. However, silver dissolution from AgO cathodes limits the shelf life and cycle life of primary and secondary AgO-Zn cells. In this study, factors including electrolyte, cell configuration, and cycling rate on silver dissolution were investigated systematically via precise identification and quantification of dissolved silver species in AgO-Zn cells. The mechanism of silver dissolution is studied by characterizing both dissolved silver species and cathode surfaces with chemical analysis including Raman spectroscopy, X-ray photoelectron spectroscopy, and Xray absorption spectroscopy. We found that reducing the complexation step within the two-step reaction of AgO to [Ag(OH)2+x]-x is key to mitigating the silver dissolution, which can be controlled by selecting the proper electrolytic species as well as cycling rate and creating rough surfaces of cathodes.

Automated summary

Printable AgO-Zn batteries are attractive for wearable devices due to their safe chemistry, high energy density, and rechargeability. However, silver dissolution from AgO cathodes limits their shelf life and cycle life. This study investigates the factors affecting silver dissolution in AgO-Zn cells, including electrolyte, cell configuration, and cycling rate. The mechanism of silver dissolution is studied through chemical analysis, and it is found that reducing the complexation step is key to mitigating silver dissolution.