Chemical and Electrochemical Pathways to Low-Carbon Iron and Steel: Article No. 33

Kerry Rippy; Robert Bell; Noemi Leick

doi:10.1038/s44296-024-00036-6

Chemical and Electrochemical Pathways to Low-Carbon Iron and Steel: Article No. 33

National Laboratory of the Rockies

Research output: Contribution to journal › Article › peer-review

Abstract

Currently, the iron and steel industry is responsible for 7% of global CO2 emissions. In this review, we summarize the operational principles of current emissions-intensive steelmaking technologies and review emerging low- and zero-carbon technologies that could substantially reduce emissions. Current technologies that are discussed include blast furnaces, electric arc furnaces, and smelting. Promising low-carbon routes include use of alternative reductants for ore processing (hydrogen direct reduction, hydrogen plasma-smelting, hydrogen smelting, and ammonia-based reduction), electrolytic iron production (with aqueous and molten oxide electrolytes) and biocarbon-based electric arc furnace operation. Advantages of each approach are presented, and remaining research hurdles are identified.

Original language	American English
Number of pages	10
Journal	npj Materials Sustainability
Volume	2
DOIs	https://doi.org/10.1038/s44296-024-00036-6
State	Published - 2024

NLR Publication Number

NLR/JA-5500-89236

Keywords

aqueous electrolysis
electric arc furnace
electroytic steel
green iron
green steel
hydrogen DRI
hydrogen plasma smelting
industrial decarbonization
industrial electrification
molten salt electrolysis

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10.1038/s44296-024-00036-6

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title = "Chemical and Electrochemical Pathways to Low-Carbon Iron and Steel: Article No. 33",

abstract = "Currently, the iron and steel industry is responsible for 7\% of global CO2 emissions. In this review, we summarize the operational principles of current emissions-intensive steelmaking technologies and review emerging low- and zero-carbon technologies that could substantially reduce emissions. Current technologies that are discussed include blast furnaces, electric arc furnaces, and smelting. Promising low-carbon routes include use of alternative reductants for ore processing (hydrogen direct reduction, hydrogen plasma-smelting, hydrogen smelting, and ammonia-based reduction), electrolytic iron production (with aqueous and molten oxide electrolytes) and biocarbon-based electric arc furnace operation. Advantages of each approach are presented, and remaining research hurdles are identified.",

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language = "American English",

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journal = "npj Materials Sustainability",

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T1 - Chemical and Electrochemical Pathways to Low-Carbon Iron and Steel

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AU - Rippy, Kerry

AU - Bell, Robert

AU - Leick, Noemi

PY - 2024

Y1 - 2024

N2 - Currently, the iron and steel industry is responsible for 7% of global CO2 emissions. In this review, we summarize the operational principles of current emissions-intensive steelmaking technologies and review emerging low- and zero-carbon technologies that could substantially reduce emissions. Current technologies that are discussed include blast furnaces, electric arc furnaces, and smelting. Promising low-carbon routes include use of alternative reductants for ore processing (hydrogen direct reduction, hydrogen plasma-smelting, hydrogen smelting, and ammonia-based reduction), electrolytic iron production (with aqueous and molten oxide electrolytes) and biocarbon-based electric arc furnace operation. Advantages of each approach are presented, and remaining research hurdles are identified.

AB - Currently, the iron and steel industry is responsible for 7% of global CO2 emissions. In this review, we summarize the operational principles of current emissions-intensive steelmaking technologies and review emerging low- and zero-carbon technologies that could substantially reduce emissions. Current technologies that are discussed include blast furnaces, electric arc furnaces, and smelting. Promising low-carbon routes include use of alternative reductants for ore processing (hydrogen direct reduction, hydrogen plasma-smelting, hydrogen smelting, and ammonia-based reduction), electrolytic iron production (with aqueous and molten oxide electrolytes) and biocarbon-based electric arc furnace operation. Advantages of each approach are presented, and remaining research hurdles are identified.

KW - aqueous electrolysis

KW - electric arc furnace

KW - electroytic steel

KW - green iron

KW - green steel

KW - hydrogen DRI

KW - hydrogen plasma smelting

KW - industrial decarbonization

KW - industrial electrification

KW - molten salt electrolysis

U2 - 10.1038/s44296-024-00036-6

DO - 10.1038/s44296-024-00036-6

M3 - Article

SN - 2948-1775

VL - 2

JO - npj Materials Sustainability

JF - npj Materials Sustainability

ER -

Chemical and Electrochemical Pathways to Low-Carbon Iron and Steel: Article No. 33

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Keywords

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