Materials and structural design for preferable Zn deposition behavior toward stable Zn anodes

Benefiting from the high capacity of Zn metal anodes and intrinsic safety of aqueous electrolytes, rechargeable Zn ion batteries (ZIBs) show promising application in the post-lithium-ion period, exhibiting good safety, low cost, and high energy density. However, its commercialization still faces problems with low Coulombic efficiency and unsatisfied cycling performance due to the poor Zn/Zn2+ reversibility that occurred on the Zn anode. To improve the stability of the Zn anode, optimizing the Zn deposition behavior is an efficient way, which can enhance the subsequent striping efficiency and limit the dendrite growth. The Zn deposition is a controlled kinetics-diffusion joint process that is affected by various factors, such as the interaction between Zn2+ ions and Zn anodes, ion concentration gradient, and current distribution. In this review, from an electrochemical perspective, we first overview the factors affecting the Zn deposition behavior and summarize the modification principles. Subsequently, strategies proposed for interfacial modification and 3D structural design as well as the corresponding mechanisms are summarized. Finally, the existing challenges, perspectives on further development direction, and outlook for practical applications of ZIBs are proposed.

Automated summary

In order to improve the stability of the Zn anode, optimizing the Zn deposition behavior is an efficient way to enhance subsequent striping efficiency and limit dendrite growth. The Zn deposition is a controlled kinetics-diffusion joint process that is affected by factors such as the interaction between Zn2+ ions and Zn anodes, ion concentration gradient, and current distribution. This review provides an electrochemical perspective on the factors affecting Zn deposition behavior, summarizes modification principles, and discusses strategies for interfacial modification and 3D structural design along with their corresponding mechanisms.