Stimulating Zn2+ permselectivity for prominent zinc anode reversibility by designing a self-assembled artificial layer.

• A unique silane coupling agent derivative-coated Zn anode with ion perselectivity was demonstrated. • This modified Zn anode greatly restrained side reaction with desolvation of [Zn(H 2 O)6]2−. • Versatile coating with tightly contact of nano particles and organic network contributed to full-cell long cycling life. Although zinc anodes are extensively adopted to meet aqueous energy storage, serious dendrite formation and side reaction resulting in inferior lifetime have hindered the application. In this work, a unique interfacial engineering is proposed by a self-assembled artificial layer tightly contact to the surface of zinc anode with Zn2+ permselectivity. Such artificial layer via a facile hydrolysis consists of nano inorganic particles well dispersed in organic network. The screening for the bound water of Zn2+ enables excellent anticorrosion during cycling and rest situation. Meanwhile, the modified zinc anode can reduce the Zn2+ nucleation barrier for uniform distribution, which is beneficial to dendrite suppression. Consequently, the modified zinc anodes in both symmetric and full cells exhibit prominently electrochemical reversibility. Specifically, with a cycling area capacity of 3.0 mAh cm−2 at 1.0 mA cm−2, the modified zinc anode can tolerate superior plating/stripping behavior over 1000 h. When it is coupled with vanadium pentoxide cathode, the performance advantage of the modified full-cell is still impressive and high-capacity retention of ∼84 % after 1200 cycles is achieved. [ABSTRACT FROM AUTHOR]