用于无碳电化学炼铁的非消耗性氩等离子阳极

IF 21.1 1区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Sen Feng , Junjie Zhang , Junli Xu , Mouhamadou Aziz Diop , Aimin Liu , Fengguo Liu , Xianwei Hu , Zhaowen Wang , Miroslav Boča , Zhongning Shi
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引用次数: 0

摘要

高炉炼铁会产生大量二氧化碳,而熔融氧化物电解(MOE)因其无碳排放而在炼铁领域引起了极大的兴趣。然而,阳极是关键的限制因素,由于高温和高强度氧化气氛,阳极具有很大的挑战性。为此,我们提出了一种用于铁电解的非消耗性氩等离子阳极,作为一种新的技术工艺。在电解过程中,氩发生阳极电离,形成 Ar+,并喷射到熔融氧化物电解质中,与电解质中的 O2- 复阴离子发生反应。通过阴极还原可获得金属铁,而在电解质中通过 2O2- (络合物) + 4Ar+ = O2 + 4Ar 可实现氧气进化和氩气再生,这证明了氩等离子体作为熔融氧化物电解的非消耗性阳极的可操作性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A non-consumable argon plasma anode for carbon-free electrochemical ironmaking

A non-consumable argon plasma anode for carbon-free electrochemical ironmaking

Blast furnace ironmaking produces abundant CO2, and molten oxide electrolysis (MOE) attracts great interest in ironmaking due to its carbon-free emissions. However, the anodes are the key limiting factor, making them very challenging due to high temperature and the intensive oxidation atmosphere. In this respect, a non-consumable argon plasma anode for iron electrolysis is proposed as a new technological process. During electrolysis, argon ionizes anodically and forms Ar+, which will jet into the molten oxide electrolyte and react with the O2– complex anion from the electrolyte. Metallic iron is obtained by cathodic reduction, while oxygen evolution and argon regeneration occur in the electrolyte through 2O2–(complex) + 4Ar+ = O2 + 4Ar, demonstrating the workability of the argon plasma as a non-consumable anode for molten oxide electrolysis.

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来源期刊
Materials Today
Materials Today 工程技术-材料科学:综合
CiteScore
36.30
自引率
1.20%
发文量
237
审稿时长
23 days
期刊介绍: Materials Today is the leading journal in the Materials Today family, focusing on the latest and most impactful work in the materials science community. With a reputation for excellence in news and reviews, the journal has now expanded its coverage to include original research and aims to be at the forefront of the field. We welcome comprehensive articles, short communications, and review articles from established leaders in the rapidly evolving fields of materials science and related disciplines. We strive to provide authors with rigorous peer review, fast publication, and maximum exposure for their work. While we only accept the most significant manuscripts, our speedy evaluation process ensures that there are no unnecessary publication delays.
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