Electrolyte additive engineering for aqueous Zn ion batteries

Aqueous Zn ion batteries (AZIBs) are one of the most promising new-generation electrochemical energy storage devices with high specific capacity, good security, and economic benefits. The electrolyte acts as a bridge connecting cathode and anode, providing a realistic working environment. However, using aqueous electrolytes presents many challenges for cathode (dissolution, electrostatic interaction, by-products) and anode (Zn dendrite, side reactions). As an innovative and maneuverable technology, additive engineering has effectively solved electrodes' critical problems. Therefore, it is essential to systematically summarize additive engineering and explore new perspectives in response to the existing issues. Based on the challenges of electrolytes for electrodes, the review focuses on an overview of the effects of additive engineering on cathode and anode, respectively. Additive engineering can improve the problems existing in the cathode, such as relieving dissolution, adjusting electrostatic interaction, and reducing by-products. The effects on anode are summarized in aspects of inhibiting Zn dendrites and reducing side reactions. In addition, the effects of different additives on the charge storage mechanism as well as the kinetic characteristics of AZIBs are described separately. Finally, the potential directions and development prospects for further improvement of additive engineering in AZIBs are proposed.

Automated summary

Aqueous Zn ion batteries (AZIBs) are a promising electrochemical energy storage device. Additive engineering is an innovative and flexible technology that effectively solves the challenges faced by AZIBs cathode and anode. This review summarizes the effects of additive engineering on cathode and anode, as well as the influence on charge storage mechanism and kinetic characteristics of AZIBs.