Quasi-Liquid Gel Electrolyte for Enhanced Flexible Zn–Air Batteries

Nuo Shang; Keliang Wang; Manhui Wei; Yayu Zuo; Pengfei Zhang; Hengwei Wang; Zhuo Chen; Daiyuan Zhong; Pucheng Pei

doi:10.1002/adfm.202303719

Quasi-Liquid Gel Electrolyte for Enhanced Flexible Zn–Air Batteries

Nuo Shang, Keliang Wang^*, Manhui Wei, Yayu Zuo, Pengfei Zhang, Hengwei Wang, Zhuo Chen, Daiyuan Zhong, Pucheng Pei

^*此作品的通讯作者

机械与车辆学院

科研成果: 期刊稿件 › 文章 › 同行评审

21 引用（Scopus）

摘要

Flexible Zn–air batteries (FZABs) have attracted more attention due to their high specific energy, excellent stability, and unique rechargeability. However, these batteries are limited by the low conductivity of the gel electrolytes used. Here a quasi-liquid gel with ionic conductivity comparable to liquid electrolytes is presented. The gel pore structure is guided and modified in situ with large-size silica to achieve clear and unbroken pores. The reduced skeleton structure leads to a significant increase in ionic conductivity to 562.6 mS cm⁻¹, enabling a peak power density of 154 mW cm⁻² and a cycle life of over 40 h with a low charge–discharge gap. The FZABs also exhibit a high lifetime and potential advantages in 10 mA cm⁻² charge/discharge testing, and demonstrate excellent performance in practical applications. This study offers new possibilities for developing high-performance quasi-liquid gels and innovative concepts for FZABs.

源语言	英语
文章编号	2303719
期刊	Advanced Functional Materials
卷	33
期	35
DOI	https://doi.org/10.1002/adfm.202303719
出版状态	已出版 - 29 8月 2023

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abstract = "Flexible Zn–air batteries (FZABs) have attracted more attention due to their high specific energy, excellent stability, and unique rechargeability. However, these batteries are limited by the low conductivity of the gel electrolytes used. Here a quasi-liquid gel with ionic conductivity comparable to liquid electrolytes is presented. The gel pore structure is guided and modified in situ with large-size silica to achieve clear and unbroken pores. The reduced skeleton structure leads to a significant increase in ionic conductivity to 562.6 mS cm−1, enabling a peak power density of 154 mW cm−2 and a cycle life of over 40 h with a low charge–discharge gap. The FZABs also exhibit a high lifetime and potential advantages in 10 mA cm−2 charge/discharge testing, and demonstrate excellent performance in practical applications. This study offers new possibilities for developing high-performance quasi-liquid gels and innovative concepts for FZABs.",

keywords = "Zn–air batteries, cryo-SEM, flexible batteries, green energy, in situ modification",

author = "Nuo Shang and Keliang Wang and Manhui Wei and Yayu Zuo and Pengfei Zhang and Hengwei Wang and Zhuo Chen and Daiyuan Zhong and Pucheng Pei",

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T1 - Quasi-Liquid Gel Electrolyte for Enhanced Flexible Zn–Air Batteries

AU - Shang, Nuo

AU - Wang, Keliang

AU - Wei, Manhui

AU - Zuo, Yayu

AU - Zhang, Pengfei

AU - Wang, Hengwei

AU - Chen, Zhuo

AU - Zhong, Daiyuan

AU - Pei, Pucheng

PY - 2023/8/29

Y1 - 2023/8/29

N2 - Flexible Zn–air batteries (FZABs) have attracted more attention due to their high specific energy, excellent stability, and unique rechargeability. However, these batteries are limited by the low conductivity of the gel electrolytes used. Here a quasi-liquid gel with ionic conductivity comparable to liquid electrolytes is presented. The gel pore structure is guided and modified in situ with large-size silica to achieve clear and unbroken pores. The reduced skeleton structure leads to a significant increase in ionic conductivity to 562.6 mS cm−1, enabling a peak power density of 154 mW cm−2 and a cycle life of over 40 h with a low charge–discharge gap. The FZABs also exhibit a high lifetime and potential advantages in 10 mA cm−2 charge/discharge testing, and demonstrate excellent performance in practical applications. This study offers new possibilities for developing high-performance quasi-liquid gels and innovative concepts for FZABs.

AB - Flexible Zn–air batteries (FZABs) have attracted more attention due to their high specific energy, excellent stability, and unique rechargeability. However, these batteries are limited by the low conductivity of the gel electrolytes used. Here a quasi-liquid gel with ionic conductivity comparable to liquid electrolytes is presented. The gel pore structure is guided and modified in situ with large-size silica to achieve clear and unbroken pores. The reduced skeleton structure leads to a significant increase in ionic conductivity to 562.6 mS cm−1, enabling a peak power density of 154 mW cm−2 and a cycle life of over 40 h with a low charge–discharge gap. The FZABs also exhibit a high lifetime and potential advantages in 10 mA cm−2 charge/discharge testing, and demonstrate excellent performance in practical applications. This study offers new possibilities for developing high-performance quasi-liquid gels and innovative concepts for FZABs.

KW - Zn–air batteries

KW - cryo-SEM

KW - flexible batteries

KW - green energy

KW - in situ modification

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SN - 1616-301X

VL - 33

JO - Advanced Functional Materials

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ER -

Quasi-Liquid Gel Electrolyte for Enhanced Flexible Zn–Air Batteries

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