Working Zinc–Air Batteries at 80 °C

Chang Xin Zhao; Legeng Yu; Jia Ning Liu; Juan Wang; Nan Yao; Xi Yao Li; Xiang Chen; Bo Quan Li; Qiang Zhang

doi:10.1002/anie.202208042

Working Zinc–Air Batteries at 80 °C

Chang Xin Zhao, Legeng Yu, Jia Ning Liu, Juan Wang, Nan Yao, Xi Yao Li, Xiang Chen, Bo Quan Li^*, Qiang Zhang^*

^*此作品的通讯作者

前沿交叉科学研究院

科研成果: 期刊稿件 › 文章 › 同行评审

61 引用（Scopus）

摘要

Aqueous zinc–air batteries possess inherent safety and are especially commendable facing high-temperature working conditions. However, their working feasibility at high temperatures has seldom been investigated. Herein, the working feasibility of high-temperature zinc–air batteries is systemically investigated. The effects of temperature on air cathode, zinc anode, and aqueous electrolyte are decoupled to identify the favorable and unfavorable factors. Specifically, parasitic hydrogen evolution reaction strengthens at high temperatures and leads to declined anode Faraday efficiency, which is identified as the main bottleneck. Moreover, zinc–air batteries demonstrate cycling feasibility at 80 °C. This work reveals the potential of zinc–air batteries to satisfy energy storage at high temperatures and guides further development of advanced batteries towards harsh working conditions.

源语言	英语
文章编号	e202208042
期刊	Angewandte Chemie - International Edition
卷	61
期	33
DOI	https://doi.org/10.1002/anie.202208042
出版状态	已出版 - 15 8月 2022

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title = "Working Zinc–Air Batteries at 80 °C",

abstract = "Aqueous zinc–air batteries possess inherent safety and are especially commendable facing high-temperature working conditions. However, their working feasibility at high temperatures has seldom been investigated. Herein, the working feasibility of high-temperature zinc–air batteries is systemically investigated. The effects of temperature on air cathode, zinc anode, and aqueous electrolyte are decoupled to identify the favorable and unfavorable factors. Specifically, parasitic hydrogen evolution reaction strengthens at high temperatures and leads to declined anode Faraday efficiency, which is identified as the main bottleneck. Moreover, zinc–air batteries demonstrate cycling feasibility at 80 °C. This work reveals the potential of zinc–air batteries to satisfy energy storage at high temperatures and guides further development of advanced batteries towards harsh working conditions.",

keywords = "Air Cathodes, Electrolytes, High Temperature, Zinc Anodes, Zinc–Air Batteries",

author = "Zhao, {Chang Xin} and Legeng Yu and Liu, {Jia Ning} and Juan Wang and Nan Yao and Li, {Xi Yao} and Xiang Chen and Li, {Bo Quan} and Qiang Zhang",

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T1 - Working Zinc–Air Batteries at 80 °C

AU - Zhao, Chang Xin

AU - Yu, Legeng

AU - Liu, Jia Ning

AU - Wang, Juan

AU - Yao, Nan

AU - Li, Xi Yao

AU - Chen, Xiang

AU - Li, Bo Quan

AU - Zhang, Qiang

PY - 2022/8/15

Y1 - 2022/8/15

N2 - Aqueous zinc–air batteries possess inherent safety and are especially commendable facing high-temperature working conditions. However, their working feasibility at high temperatures has seldom been investigated. Herein, the working feasibility of high-temperature zinc–air batteries is systemically investigated. The effects of temperature on air cathode, zinc anode, and aqueous electrolyte are decoupled to identify the favorable and unfavorable factors. Specifically, parasitic hydrogen evolution reaction strengthens at high temperatures and leads to declined anode Faraday efficiency, which is identified as the main bottleneck. Moreover, zinc–air batteries demonstrate cycling feasibility at 80 °C. This work reveals the potential of zinc–air batteries to satisfy energy storage at high temperatures and guides further development of advanced batteries towards harsh working conditions.

AB - Aqueous zinc–air batteries possess inherent safety and are especially commendable facing high-temperature working conditions. However, their working feasibility at high temperatures has seldom been investigated. Herein, the working feasibility of high-temperature zinc–air batteries is systemically investigated. The effects of temperature on air cathode, zinc anode, and aqueous electrolyte are decoupled to identify the favorable and unfavorable factors. Specifically, parasitic hydrogen evolution reaction strengthens at high temperatures and leads to declined anode Faraday efficiency, which is identified as the main bottleneck. Moreover, zinc–air batteries demonstrate cycling feasibility at 80 °C. This work reveals the potential of zinc–air batteries to satisfy energy storage at high temperatures and guides further development of advanced batteries towards harsh working conditions.

KW - Air Cathodes

KW - Electrolytes

KW - High Temperature

KW - Zinc Anodes

KW - Zinc–Air Batteries

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ER -

Working Zinc–Air Batteries at 80 °C

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