Ultra-High Temperature Molten Oxide Electrochemistry

Mingyong Wang; Handong Jiao; Zhenghao Pu; Biao Hong; Jianbang Ge; Wei Xiao; Shuqiang Jiao

doi:10.1002/anie.202206482

Ultra-High Temperature Molten Oxide Electrochemistry

Mingyong Wang, Handong Jiao, Zhenghao Pu, Biao Hong, Jianbang Ge, Wei Xiao^*, Shuqiang Jiao^*

^*此作品的通讯作者

先进结构技术研究院

科研成果: 期刊稿件 › 文献综述 › 同行评审

7 引用（Scopus）

摘要

Recently, the ultra-high temperature electrochemistry (UTE, about >1000 °C) has emerged, which represents an exploration to extend the temperature limit of human technology in electrochemical engineering. UTE has far-reaching impact on revolutionary low-carbon metal extraction and the in situ production of oxygen for deep-space exploration. It is hence of urgency to systematically summarize the development of UTE. In this Review, the basic concepts of UTE and the physicochemical properties of molten oxides are analyzed. The principles in the design of inert anodes for the oxygen evolution reaction in molten oxides are discussed, which forms a solid basis for the in situ production of oxygen from simulated lunar regolith by UTE. Furthermore, liquid metal cathodes for revolutionary titanium extraction and ironmaking/steelmaking are highlighted. With emphasis on the key challenges and perspectives, the Review can provide valuable inspiration for the rapid advancement of UTE.

源语言	英语
文章编号	e202206482
期刊	Angewandte Chemie - International Edition
卷	61
期	32
DOI	https://doi.org/10.1002/anie.202206482
出版状态	已出版 - 8 8月 2022

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title = "Ultra-High Temperature Molten Oxide Electrochemistry",

abstract = "Recently, the ultra-high temperature electrochemistry (UTE, about >1000 °C) has emerged, which represents an exploration to extend the temperature limit of human technology in electrochemical engineering. UTE has far-reaching impact on revolutionary low-carbon metal extraction and the in situ production of oxygen for deep-space exploration. It is hence of urgency to systematically summarize the development of UTE. In this Review, the basic concepts of UTE and the physicochemical properties of molten oxides are analyzed. The principles in the design of inert anodes for the oxygen evolution reaction in molten oxides are discussed, which forms a solid basis for the in situ production of oxygen from simulated lunar regolith by UTE. Furthermore, liquid metal cathodes for revolutionary titanium extraction and ironmaking/steelmaking are highlighted. With emphasis on the key challenges and perspectives, the Review can provide valuable inspiration for the rapid advancement of UTE.",

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author = "Mingyong Wang and Handong Jiao and Zhenghao Pu and Biao Hong and Jianbang Ge and Wei Xiao and Shuqiang Jiao",

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AU - Wang, Mingyong

AU - Jiao, Handong

AU - Pu, Zhenghao

AU - Hong, Biao

AU - Ge, Jianbang

AU - Xiao, Wei

AU - Jiao, Shuqiang

PY - 2022/8/8

Y1 - 2022/8/8

N2 - Recently, the ultra-high temperature electrochemistry (UTE, about >1000 °C) has emerged, which represents an exploration to extend the temperature limit of human technology in electrochemical engineering. UTE has far-reaching impact on revolutionary low-carbon metal extraction and the in situ production of oxygen for deep-space exploration. It is hence of urgency to systematically summarize the development of UTE. In this Review, the basic concepts of UTE and the physicochemical properties of molten oxides are analyzed. The principles in the design of inert anodes for the oxygen evolution reaction in molten oxides are discussed, which forms a solid basis for the in situ production of oxygen from simulated lunar regolith by UTE. Furthermore, liquid metal cathodes for revolutionary titanium extraction and ironmaking/steelmaking are highlighted. With emphasis on the key challenges and perspectives, the Review can provide valuable inspiration for the rapid advancement of UTE.

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KW - Liquid Cathodes

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KW - Oxygen Production

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ER -

Ultra-High Temperature Molten Oxide Electrochemistry

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