Matériaux & Techniques
Volume 111, Number 4, 2023
Special Issue on ‘The role of Hydrogen in the transition to a sustainable steelmaking process’; edited by Ismael Matino and Valentina Colla
Article Number 405
Number of page(s) 9
Section Metals and alloys
Published online 14 December 2023
  1. Statistics from World Steel Association, various production data updates published during 2022 and 2023 [Google Scholar]
  2. Statistics from Midrex, various 2022 and 2023 editions of ‘Direct from Midrex’ xx xxxx [Google Scholar]
  3. 2022 / [Google Scholar]
  4. F. Patisson, O. Mirgaux, J.-P. Birat, Hydrogen steelmaking, part 1: physical chemistry and process metallurgy, Matériaux & Techniques 109 (3-4), 303 (2021) [Google Scholar]
  5. J.-P. Birat, F. Patisson, O. Mirgaux, Hydrogen steelmaking, part 2: competition with other net-zero steelmaking solution − geopolitical issues, Matériaux & Techniques 109 (3-4), 307 (2021) [Google Scholar]
  6. J. von Schéele, P.C. Mathur, Solutions for immediate and transition term decarbonization, in: Proc. 6th European Steel Technology and Application Days (ESTAD), 2023, Duesseldorf, Germany. [Google Scholar]
  7. A. Hauser et al., Valorizing steelworks gases by coupling novel methane and methanol synthesis reactors with an economic hybrid model predictive controller, Metals 12 (6), 1023 (2022) [CrossRef] [Google Scholar]
  8. A. Zaccara et al., Renewable hydrogen production processes for the off-gas valorization in integrated steelworks through hydrogen intensified methane and methanol syntheses, Metals. 10 (11), 1535 (2020) [CrossRef] [Google Scholar]
  9. I. Matino et al., Hydrogen role in the valorization of integrated steelworks process off-gases through methane and methanol syntheses, Matériaux & Techniques, 109 (3-4), 308 (2021) [CrossRef] [EDP Sciences] [Google Scholar]
  10. L. Deng et al., Techno-economic analysis of coke oven gas and blast 532 furnace gas to methanol process with carbon dioxide capture and utilization, Energy Conv. 533 Manag. 204, 112315 (2020) [CrossRef] [Google Scholar]
  11. B. Karlson et al., Commercializing LanzaTech, from waste to fuel: an effectuation case, J. Manag. Organ. 27 (1), 1–22 (2018) [Google Scholar]
  12. [Google Scholar]
  13. A. Olsece et al., Reduction of gaseous emissions by applying a spray-scrubber-based process for cyanide compounds reduction in blast furnace gas, presented at AISTech 2023 − The Iron & Steel Technology Conference and Exposition, May 2023, Detroit (USA) [Google Scholar]
  14. P.C. Mathur, J. von Schéele, R.K. Nath, Solutions to decarbonize iron & steel making, Steel & Metallurgy, April, 2021 [Google Scholar]
  15. J. von Schéele et al., Hydrogen steelmaking − solutions for melting and reheating, Steel Times International, March, 2021, pp. 36–39 [Google Scholar]
  16. J.O. Edström, Järnsvampsprocesser, in: Järn- och stålframställning: utvecklingen i Sverige 1850 till 2000, Jernkontoret, 2004, pp. 126–153. [Google Scholar]
  17. I.N. Zaini et al., Decarbonising the iron and steel industries: production of carbon-negative direct reduced iron by using biosyngas, Energy Conv. Manag. 281 (11), 116806 (2023) [CrossRef] [Google Scholar]
  18. P.C. Mathur, J. von Schéele, Decarbonizing solutions for steel, Steel Times International, April, 2021, pp. 35–39 [Google Scholar]
  19. U. Zanusso et al., Development and testing of flameless burner fed by NG/H2 mix, Matériaux & Techniques 109 (3-4), 304 (2021) [Google Scholar]
  20. I. Luzzo et al., Feasibility study for utilization of natural gas and hydrogen blends on industrial furnaces, Matériaux & Techniques 109 (3-4), 306 (2021) [Google Scholar]
  21. A. Della Rocca et al., Rolling mill decarbonisation: Tenova Smartburners with 100% hydrogen, Matériaux & Techniques 109 (3-4), 309 (2021) [Google Scholar]
  22. P.C. Mathur et al., CoJet® − 25 years of revolutionizing EAF steelmaking, Steel Tech, Vol. 15, No. 4, July, 2021, pp. 65–71 [Google Scholar]
  23. W.J. Mahoney et al., The critical role of hydrogen in Linde’s coherent jet technology, Proceedings AISTech, 8–11 May, 2023, Detroit, USA [Google Scholar]
  24. J. von Schéele, Hydrogen flameless oxyfuel for CO2 free heating, Millennium Steel, May, 2021, pp. 32–35 [Google Scholar]
  25. J. von Schéele, Advancing Use of hydrogen as fuel in Steelmaking, Millenium Steel, May, 2022, pp. 20–22 [Google Scholar]
  26. J. von Schéele, H. Alshawarghi, D. Razzari, Technologies paving the way to carbon neutral stainless steel production, La Metallurgia Italiana, July/August, 2022, pp. 53–61 [Google Scholar]
  27. C. Nakkhong et al., Successful results from improved sustainability by using flameless oxyfuel in SYS, Proceedings 2019 Annual Meeting & Conference of South-East Asia Iron and Steel Institute (SEASI), June 16–19, 2019, Bangkok, Thailand [Google Scholar]
  28. J. von Schéele, Impact of decarbonisation on the steel industry structure, Green Steel World, April, 2023, pp. 28–31 [Google Scholar]
  29. J. von Schéele, From biggest in grey to biggest in green, Chapter on China in Touching Hydrogen Future − Tour Around the Globe, 157–172 [Google Scholar]
  30. [Google Scholar]
  31. R. Valentini et al., Application of laboratory and on field techniques to determine the risk of hydrogen embrittlement in gaseous hydrogen and relative mixtures transport and storage, Matériaux & Techniques, 111 (2), 202 (2023) [CrossRef] [EDP Sciences] [Google Scholar]
  32. J. von Schéele, P. Samuelsson, Improving life-cycle of stainless steel: from start to finish, Stainless Steel World Americas, June, 2022, pp. 10–11 [Google Scholar]

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