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Abstract Aqueous zinc‐ion batteries feature high safety, low cost, and relatively high energy density; however, their cycle life is hindered by severe Zn dendrite formation and water‐induced parasitic reactions. Herein, a porous polyaniline (PANI) interfacial layer is developed on the surface of Zn metal anode to regulate the transport and deposition of Zn 2+ , achieving an ultra‐stable and highly reversible Zn anode. Specifically, the abundant polar groups (NH and N) in PANI have a strong attraction to H 2 O, which can trap and immobilize H 2 O molecules around Zn 2+ . Moreover, the protective layer regulates ion flux and deposition behavior of Zn 2+ through the ion confinement effect. Consequently, the Zn@PANI anode exhibits improved reversible plating/stripping behavior with a low nucleation overpotential (37.9 mV) at 2.0 mA cm ‐2 compared to that of bare Zn anode. The MnO 2 //Zn@PANI cell demonstrates a high capacity retention of 94.3% after 1000 cycles at 1.0 A g −1 . This study lays the foundation for accessible interface engineering and in‐depth mechanistic analysis of Zn anode.
Li et al. (Thu,) studied this question.