Sustainable Ironmaking Toward a Future Circular Steel Economy: Exploiting a Critical Oxygen Concentration for Metallurgical Cu Removal from Scrap‐Based Melts

Souza Filho, Isnaldi R.; da Silva, Alisson K.; Büyükuslu, Ömer K.; Raabe, Dierk; Springer, Hauke

doi:10.1002/srin.202300785

steel research int.

2024

DOI: 10.1002/srin.202300785

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Sustainable Ironmaking Toward a Future Circular Steel Economy: Exploiting a Critical Oxygen Concentration for Metallurgical Cu Removal from Scrap‐Based Melts

Isnaldi R. Souza Filho,

Alisson K. da Silva,

Ömer K. Büyükuslu

et al.

Abstract: A circular steel economy based on recycling scrap is severely hampered by the increasing accumulation of Cu returning from more and more electrified products, which severely limits processing, application, and safety of steels. As of yet, no viable strategies for its removal have been developed, and the increasing Cu contamination can only be diluted with fresh primary iron. This is not only evoking CO2 emissions from conventional reduction processes, but also merely delays the problem until global demands all… Show more

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Cited by 4 publications

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Hydrogen Plasma for Low-Carbon Extractive Metallurgy: Oxides Reduction, Metals Refining, and Wastes Processing

Satritama,

Cooper,

Fellicia

et al. 2024

J. Sustain. Metall.

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Carbon-rich sources, such as coal and carbon monoxide gas, have been extensively used in the metal industry as the reducing agent of metal oxides and as the energy source for metal production. Consequently, the extractive metal sector contributes to approximately 9.5% of global greenhouse gas emissions. Hydrogen gas offers a promising alternative to using carbon in metallurgical processes as an eco-friendly reductant and energy provider that produces water vapor as a by-product. However, molecular hydrogen has some barriers to implementation. These primarily concern the thermodynamics and kinetics of metal oxide reduction. To address these issues, researchers have explored the use of hydrogen plasma, which is generated by applying high energy to molecular hydrogen to produce atomic, ionic, and excited hydrogen species. Hydrogen plasma has thermodynamic and kinetic advantages over molecular hydrogen and carbon-based reductants since it exhibits a lower standard Gibbs free energy of reaction for H2O formation and a lower activation energy. Hydrogen plasma is also a versatile reductant as it is proven on a laboratory scale to produce metal in fewer steps, process a wide range of oxides feed and feed sizes, and be used to refine metals. There are, however, some limitations to using hydrogen plasma in extractive metallurgy. These include the cost of electricity, potential back reactions or reoxidation, and industrial scale-up challenges such as heat utilization or heat loss minimization. This study undertakes a comprehensive review of prior research on the use of hydrogen plasma for metal oxides reduction and reviewing state-of-the-art techniques for its use in extractive metallurgy applications. An overview of hydrogen plasma utilization for producing and refining several metals from primary or secondary feed materials, the many types of plasma reactors, and the commonly used parameters for each metal production process are also presented. Prospects and potential feasibility of the hydrogen plasma route are also discussed.Graphical Abstract

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Hydrogen Plasma for Low-Carbon Extractive Metallurgy: Oxides Reduction, Metals Refining, and Wastes Processing

Satritama,

Cooper,

Fellicia

et al. 2024

J. Sustain. Metall.

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Mechanisms and elemental partitioning during simultaneous dephosphorization and reduction of Fe-O-P melts by hydrogen plasma

Büyükuslu,

Aota,

Raabe

et al. 2024

Acta Materialia

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Decarbonizing the global steel industry in a resource-constrained future—a systems perspective

Watari,

McLellan

2024

Phil. Trans. R. Soc. A.

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Decarbonizing the global steel industry hinges on three key limited resources: geological carbon storage, zero-emission electricity and end-of-life scrap. Existing system analysis calls for an accelerated expansion of the supply of these resources to meet the assumed ever-increasing steel demand. In this study, we propose a different view on how to decarbonize the global steel industry, based on the principle that resource supply can only expand in line with historical trends and actual construction plans. Our analysis shows that global steel production cannot grow any further within a Paris-compatible carbon budget, resulting in a shortfall of approximately 30% against 2050 demand. This trajectory involves the phasing out of blast furnaces, along with strong growth in scrap recycling and hydrogen-based production. These findings highlight critical yet often overlooked challenges: (i) reducing excess demand while providing essential services, (ii) producing high-grade steel through upcycling scrap, and (iii) ensuring an equitable distribution of limited production across the globe. These perspectives contrast with those of the current agenda, which largely emphasizes the need to invest in new production technologies. Grounded in a physical basis, this analysis offers a complementary perspective for a more balanced debate in policymaking and industrial strategy. This article is part of the discussion meeting issue ‘Sustainable metals: science and systems’.

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Sustainable Ironmaking Toward a Future Circular Steel Economy: Exploiting a Critical Oxygen Concentration for Metallurgical Cu Removal from Scrap‐Based Melts

Cited by 4 publications

References 48 publications

Hydrogen Plasma for Low-Carbon Extractive Metallurgy: Oxides Reduction, Metals Refining, and Wastes Processing

Hydrogen Plasma for Low-Carbon Extractive Metallurgy: Oxides Reduction, Metals Refining, and Wastes Processing

Mechanisms and elemental partitioning during simultaneous dephosphorization and reduction of Fe-O-P melts by hydrogen plasma

Decarbonizing the global steel industry in a resource-constrained future—a systems perspective

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