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Enabling Stable Zn Anodes by Molecularly Engineering the Inner Helmholtz Plane with Amphiphilic Dibenzenesulfonimide Additive.

Jun YangZhiqiang HanZhiqiang WangLiying SongBusheng ZhangHongming ChenXing LiWoon-Ming LauDan Zhou
Published in: Advanced science (Weinheim, Baden-Wurttemberg, Germany) (2023)
The notorious dendrite growth and hydrogen evolution reaction (HER) are considered as main barriers that hinder the stability of the Zn-metal anode. Herein, molecular engineering is conducted to optimize the inner Helmholtz plane with a trace of amphiphilic dibenzenesulfonimide (BBI) in an aqueous electrolyte. Both experimental and computational results reveal that the BBI - binds strongly with Zn 2+ to form {Zn(BBI)(H 2 O) 4 } + in the electrical double layer and reduces the water supply to the Zn anode. During the electroplating process, {Zn(BBI)(H 2 O) 4 } + is "compressed" to the Zn anode/electrolyte interface by Zn 2+ flow, and accumulated and adsorbed on the surface of the Zn anode to form a dynamic water-poor inner Helmholtz plane to inhibit HER. Meanwhile, the{Zn(BBI)(H 2 O) 4 } + on the Zn anode surface possesses an even distribution, delivering uniform Zn 2+ flow for smooth deposition without Zn dendrite growth. Consequently, the stability of the Zn anode is largely improved with merely 0.02 M BBI - to the common electrolyte of 1 M ZnSO 4 . The assembled Zn||Zn symmetric cell can be cycled for more than 1180 h at 5 mA cm -2 and 5 mA h cm -2 . Besides, the practicability in Zn||NaV 3 O 8 ·1.5 H 2 O full cell is evaluated, which suggests efficient storage even under a high mass loading of 12 mg cm -2 .
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