Electrochemistry in Action: Iron and Steel Manufacturing

The Electrochemical Society Interface Pub Date : 2024-06-01 DOI:10.1149/2.f06242if

Trevor Braun, Colleen Wallace, Quoc Pham, Sandeep Nijhawan, Christopher L. Alexander

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Abstract

Steel is one of the most manufactured materials in modern society, with 1.9 billion metric tons produced annually for use in building materials, vehicles, wind-turbines, and appliances, among many other applications. As you might expect for something so ubiquitous, the technology used to manufacture steel is also quite mature, having been first identified over 4,000 years ago and heavily industrialized in the 19th century. The general approach is to mine iron ore from the earth’s crust and refine that ore to metallic iron (i.e., ironmaking) which is then combined with carbon and other elements to make steel products (i.e., steelmaking). However, conventional steel manufacturing relies primarily on carbon-based fuels, such as coal, to create the high temperatures (≈ 1600°C) required for the process and can emit as much as 2.2 tons of CO2 per ton of crude steel produced.1 The iron ore reduction step accounts for 90% of CO2 emissions associated with steel production. The heightened effort to decarbonize industrial process and reverse climate change is putting pressure on this 600+ year-old technology to shift to lowcarbon alternatives, especially considering that the steel industry is responsible for ≈ 7% of all global CO2 emissions annually.

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电化学在行动：钢铁制造

钢铁是现代社会制造量最大的材料之一，每年生产 19 亿吨，用于建筑材料、汽车、风力涡轮机和电器等多种用途。对于如此无处不在的材料来说，制造钢铁的技术也相当成熟，早在 4000 多年前就已出现，并在 19 世纪实现了大规模工业化。一般的方法是从地壳中开采铁矿石，然后将铁矿石提炼成金属铁（即炼铁），再与碳和其他元素结合制成钢铁产品（即炼钢）。然而，传统的钢铁生产主要依靠煤炭等碳基燃料来产生生产过程所需的高温（≈ 1600°C），每生产一吨粗钢可排放多达 2.2 吨的二氧化碳1 。1 铁矿石还原步骤占与钢铁生产相关的二氧化碳排放量的 90%。为实现工业过程脱碳和扭转气候变化所做的努力正在加大，这给这项拥有 600 多年历史的技术带来了向低碳替代品转变的压力，特别是考虑到钢铁行业每年的二氧化碳排放量占全球总排放量的 7%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Electrochemical Society Interface

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