Building Sustainable Saturated Fatty Acid-Zinc Interfacial Layer toward Ultra-Stable Zinc Metal Anodes

The commercialization pace of aqueous zinc batteries (AZBs) is seriously limited due to the uncontrolled dendrite growth and severe corrosion reaction of the zinc anode. Herein, a universal and extendable saturated fatty acid-zinc interfacial layer strategy for modulating the interfacial redox proce...

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Veröffentlicht in:	Nano letters 2023-04, Vol.23 (8), p.3573-3581
Hauptverfasser:	Fu, Meng, Yu, Huaming, Huang, Shaozhen, Li, Quanyu, Qu, Baihua, Zhou, Liangjun, Kuang, Gui-Chao, Chen, Yuejiao, Chen, Libao
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creator	Fu, Meng Yu, Huaming Huang, Shaozhen Li, Quanyu Qu, Baihua Zhou, Liangjun Kuang, Gui-Chao Chen, Yuejiao Chen, Libao
description	The commercialization pace of aqueous zinc batteries (AZBs) is seriously limited due to the uncontrolled dendrite growth and severe corrosion reaction of the zinc anode. Herein, a universal and extendable saturated fatty acid-zinc interfacial layer strategy for modulating the interfacial redox process of zinc toward ultrastable Zn metal anodes is proposed. The in situ complexing of saturated fatty acid-zinc interphases could construct an extremely thin zinc compound layer with continuously constructed zincophilic sites which kinetically regulates Zn nucleation and deposition behaviors. Furthermore, the multifunctional interfacial layer with internal hydrophobic carbon chains as a protective layer is efficient to exclude active water molecules from the surface and efficiently inhibit the surface corrosion of zinc. Consequently, the modified anode shows a long cycle life of over 4000 h at 5 mA cm–2. In addition, the assembled Zn\|\|V2O5 full cells based on modified zinc anodes have excellent rate performance and long cycle stability.
doi_str_mv	10.1021/acs.nanolett.3c00741
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title	Building Sustainable Saturated Fatty Acid-Zinc Interfacial Layer toward Ultra-Stable Zinc Metal Anodes
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