Gradient Quasi‐Solid Electrolyte Enables Selective and Fast Ion Transport for Robust Aqueous Zinc‐Ion Batteries

The quasi‐solid electrolytes (QSEs) attract extensive attention due to their improved ion transport properties and high stability, which is synergistically based on tunable functional groups and confined solvent molecules among the polymetric networks. However, the trade‐off effect between the polym...

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Bibliographic Details
Published in:Advanced materials (Weinheim) 2024-02, Vol.36 (6), p.e2308639-n/a
Main Authors: Cui, Yanglansen, Chen, Weipeng, Xin, Weiwen, Ling, Haoyang, Hu, Yuhao, Zhang, Zhehua, He, Xiaofeng, Zhao, Yong, Kong, Xiang‐Yu, Wen, Liping, Jiang, Lei
Format: Article
Language:English
Subjects:
asymmetric engineering
dendrite‐free
Electrolytic cells
epitaxial polymerization
Functional groups
hydrogel networks
Hydrogels
Ion currents
Ion transport
Molten salt electrolytes
Networks
Polymers
Skewed distributions
Solid electrolytes
Transport properties
Water chemistry
Zinc
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Summary:The quasi‐solid electrolytes (QSEs) attract extensive attention due to their improved ion transport properties and high stability, which is synergistically based on tunable functional groups and confined solvent molecules among the polymetric networks. However, the trade‐off effect between the polymer content and ionic conductivity exists in QSEs, limiting their rate performance. In this work, the epitaxial polymerization strategy is used to build the gradient hydrogel networks (GHNs) covalently fixed on zinc anode. Then, it is revealed that the asymmetric distribution of negative charges benefits GHNs with fast and selective ionic transport properties, realizing a higher Zn2+ transference number of 0.65 than that (0.52) for homogeneous hydrogel networks (HHNs) with the same polymer content. Meanwhile, the high‐density networks formed at Zn/GHNs interface can efficiently immobilize free water molecules and homogenize the Zn2+ flux, greatly inhibiting the water‐involved parasitic reactions and dendrite growth. Thus, the GHNs enable dendrite‐free stripping/plating over 1000 h at 8 mA cm−2 and 1 mAh cm−2 in a Zn||Zn symmetric cell, as well as the evidently prolonged cycles in various full cells. This work will shed light on asymmetric engineering of ion transport channels in advanced quasi‐solid battery systems to achieve high energy and safety. The gradient polymetric networks (GHNs) are fixed directly on zinc anode via the interface‐initiated epitaxial polymerization strategy. The GHNs not only favor the Zn2+ shuttle but lock the interfacial free water, alleviating the dendrite and corrosion on zinc anode. This work demonstrates the asymmetric design concept in quasi‐solid electrolytes to improve the energy density, power density, and cycling stability of aqueous zinc ion batteries (AZIBs).
ISSN:0935-9648
1521-4095
DOI:10.1002/adma.202308639