Self-assembled polyelectrolytes with ion-separation accelerating channels for highly stable Zn-ion batteries

Hu, Xueying; Dong, Haobo; Gao, Nan; Wang, Tianlei; He, Hongzhen; Gao, Xuan; Dai, Yuhang; Liu, Yiyang; Brett, Dan J. L.; Parkin, Ivan P.; He, Guanjie

Self-assembled polyelectrolytes with ion-separation accelerating channels for highly stable Zn-ion batteries

Xueying Hu, Haobo Dong (), Nan Gao, Tianlei Wang, Hongzhen He, Xuan Gao, Yuhang Dai, Yiyang Liu, Dan J. L. Brett, Ivan P. Parkin and Guanjie He ()
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Xueying Hu: University College London
Haobo Dong: University College London
Nan Gao: Jilin University
Tianlei Wang: University College London
Hongzhen He: University College London
Xuan Gao: University College London
Yuhang Dai: University College London
Yiyang Liu: Guoke Artificial Intelligence Innovation Center
Dan J. L. Brett: Guoke Artificial Intelligence Innovation Center
Ivan P. Parkin: University College London
Guanjie He: University College London

Nature Communications, 2025, vol. 16, issue 1, 1-11

Abstract: Abstract Aqueous zinc-ion batteries offer a sustainable alternative to lithium-ion batteries due to their abundance, safety, and eco-friendliness. However, challenges like hydrogen evolution and uncontrolled diffusion of H⁺, Zn²⁺, and SO₄²⁻ in the electrolyte lead to the dendrite formation, side reactions, and reduced Coulombic efficiency for Zn nucleation. Here, to simultaneously regulate the diffusion of cations and anions in the electrolyte, an ion-separation accelerating channel is constructed by introducing layer-by-layer self-assembly of a flocculant poly(allylamine hydrochloride) and its tautomer poly(acrylic acid). The dual-ion channels, created by strong electrostatic interactions between carboxylate anions and ammonia cations, block SO42− and promote the uniform Zn deposition along the Zn(002) plane, exhibiting a CE of 99.8% after 1600 cycles in the Cu||Zn cell. With the facile fabrication of the layer-by-layer self-assembled Zn anode, an Ah-level pouch cell (17.36 Ah) with a high mass loading (> 8 mg cm⁻²) demonstrates the practical viability for large-scale applications, retaining a capacity of 93.6% for 250 cycles at 1.7 C (35.3 min). This work enables more uniform Zn deposition and enhances the cycling stability in larger pouch cells, paving the way for the commercialisation of zinc-ion batteries.

Date: 2025
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DOI: 10.1038/s41467-025-57666-0

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