Zinc-based batteries (ZBs) have recently attracted wide attention energy storage with cost-
effectiveness and intrinsic safety. However, it suffers from poor interface stability between the …

The electrode/electrolyte interface plays a critical role in stabilizing the cycling performance
and prolonging the service life of rechargeable batteries to meet the sustainable energy …

The dendrite growth of zinc and the side reactions including hydrogen evolution often
degrade performances of zinc-based batteries. These issues are closely related to the …

Regulating the electrical double layer (EDL) structure via electrolyte additives is a promising
strategy to improve the cycling stability of Zn anodes, but there are no general strategies that …

Current lithium-ion batteries degrade under high rates and low temperatures due to the use
of carbonate electrolytes with restricted Li+ conduction and sluggish Li+ desolvation. Herein …

Aqueous zinc metal batteries are primarily limited due to the considerable risks of
uncontrollable electrodeposition and side reactions at the anode/electrolyte interface (AEI) …

Achieving high‐rate and high‐areal‐capacity Zn anode with high depth of discharge (DOD)
offers a bright future for large‐scale aqueous batteries. However, Zn deposition suffers from …

Owing to zinc dendrites and parasitic reactions, aqueous Zn‐metal batteries often suffer from
poor reversibility and cyclability. Electrolyte additives present a promising strategy to …

The stability of a battery is strongly dependent on the feature of solid electrolyte interphase
(SEI). The electrical double layer forms prior to the formation of SEI at the interface between …

The issues of serious corrosion and dendrite growth in electrode surface hinder the
commercialization of aqueous zinc batteries. A stable solid electrolyte interphase (SEI) on …