Litcius/Paper detail

Constructing a Multifunctional SEI Layer Enhancing Kinetics and Stabilizing Zinc Metal Anode

Dingzheng Li, Chuanlin Li, Wenjie Liu, Hongxia Bu, Xixi Zhang, Titi Li, Jing Zhang, Mengzhen Kong, Xiao Wang, Chenggang Wang, Xijin Xu

2024Advanced Functional Materials68 citationsDOIOpen Access PDF

Abstract

Abstract Zn dendrite growth and parasitic reactions at the interface of zinc anode/electrolyte in aqueous zinc batteries severely hinder its lifespan in application. Herein, the zinc anode is effectively stabilized by introducing trace amounts of 4‐aminobutane‐1‐phosphate (ABPA) into the ZnSO 4 electrolyte. The ABPA adsorbs onto the surface of zinc anode and then further decomposes to a high conductive organic/inorganic composite in situ SEI layer including amino, partial carbon chain, and zinc phosphate. In the SEI layer, the residual undecomposed carbon chain promotes the desolvation of Zn 2+ , the amino induces uniform Zn 2+ plating and zinc phosphate facilitates the migration of Zn 2+ . Thus, this in situ SEI layer not only suppresses water‐related side reactions but also enhances the Zn 2+ transport kinetics. As a result, Zn||Zn symmetric cell delivers an ultralong cycle life of over 13 000 cycles at 50 mA cm −2 and 1 mAh cm −2 . A high average Coulombic efficiency of 99.72% is achieved in over 1000 cycles in Zn||Cu half‐cell. The Zn||I 2 full cell delivers a high‐capacity retention of 91.42% after 40,000 cycles. Moreover, a 49 mAh Zn||I 2 pouch cell maintains 80.28% capacity retention over 300 cycles and 61.22% after 1000 cycles.

Topics & Concepts

Materials scienceAnodeZincKineticsLayer (electronics)MetalChemical engineeringNanotechnologyMetallurgyElectrodePhysical chemistryEngineeringQuantum mechanicsChemistryPhysicsAdvanced battery technologies researchAdvanced Battery Technologies ResearchAdvanced Battery Materials and Technologies