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Towards blast furnace ironmaking decarbonization via alternative reductants: A techno-economic and carbon assessment

 
cris.virtual.department#PLACEHOLDER_PARENT_METADATA_VALUE#
cris.virtual.orcid0000-0002-4674-8693
cris.virtualsource.department4dc8690d-192b-4218-b2b1-ba58024d9b87
cris.virtualsource.orcid4dc8690d-192b-4218-b2b1-ba58024d9b87
dc.contributor.authorAvila, Mario
dc.contributor.authorVerbrugge, Sofie
dc.contributor.authorBellemans, Inge
dc.contributor.authorVerbeken, Kim
dc.date.accessioned2026-07-16T11:51:54Z
dc.date.available2026-07-16T11:51:54Z
dc.date.createdwos2026
dc.date.issued2026
dc.description.abstractThe steel sector is one of the largest industrial contributors to global CO₂ emissions, making the decarbonization of ironmaking essential for achieving net-zero targets. This study investigates lower-carbon blast furnace (BF) operation through the partial substitution of fossil fuels with waste-derived reductants, linking industrial decarbonization with resource recovery and circular economy principles. A representative European BF-based ironmaking system was assessed under four scenarios: a conventional Benchmark Scenario (BS); the AlterCoal Scenario (AS), in which non-recyclable waste plastics partially replace coke oven coal; the Torero Scenario (TS), where pulverised coal is substituted with bio-coal from torrefied waste wood; and a combined AlterCoal–Torero Scenario (ATS).Life-cycle and techno-economic assessments were conducted to quantify the environmental and economic performance of each pathway. The results indicate reductions in total CO2 emissions of 0.55% (AS), 1.09% (TS), and 1.64% (ATS), primarily driven by the lower upstream carbon intensity and biogenic content of the alternative fuels. Economically, average gross profit increased by 9.3% (AS), 7.8% (TS), and 17.2% (ATS), mainly due to reduced exposure to energy market volatility and carbon pricing. Sensitivity and uncertainty analyses indicate enhanced economic resilience for the alternative scenarios, particularly under elevated coal and carbon price conditions. Overall, the results demonstrate that integrating waste-derived fuels into BF ironmaking can simultaneously reduce emissions and improve economic performance, offering a pragmatic transition pathway for advancing sustainable process innovation in energy-intensive industries.
dc.description.wosFundingTextThe project SMART is co-funded by the LIFE Programme of the European Union (LIFE19 CCM/BE/001215). The views and opinions expressed are solely those of the authors and do not necessarily reflect those of the European Union or the European Climate, Infrastructure and Environment Executive Agency (CINEA). The European Union and the granting authority are not responsible for any use that may be made of the information contained herein. I. Bellemans holds a grant from the Research Foundation Flanders (1239024 N).
dc.identifier.doi10.1016/j.spc.2026.05.005
dc.identifier.issn2352-5509
dc.identifier.urihttps://imec-publications.be/handle/20.500.12860/59882
dc.language.isoeng
dc.provenance.editstepusergreet.vanhoof@imec.be
dc.publisherELSEVIER
dc.source.beginpage104
dc.source.endpage126
dc.source.journalSUSTAINABLE PRODUCTION AND CONSUMPTION
dc.source.numberofpages23
dc.source.volume66
dc.subject.keywordsWASTE PLASTICS
dc.subject.keywordsCOKE-OVEN
dc.subject.keywordsBIOMASS
dc.subject.keywordsGAS
dc.subject.keywordsPRETREATMENT
dc.subject.keywordsIRON
dc.subject.keywordsTORREFACTION
dc.title

Towards blast furnace ironmaking decarbonization via alternative reductants: A techno-economic and carbon assessment

dc.typeJournal article
dspace.entity.typePublication
imec.internal.crawledAt2026-07-14
imec.internal.sourcecrawler
imec.internal.wosCreatedAt2026-07-14
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