Carbon capture and utilization in the steel industry : challenges and opportunities for chemical engineering (original) (raw)

Please use this url to cite or link to this publication:http://hdl.handle.net/1854/LU-8635595

MLA

De Ras, Kevin, et al. “Carbon Capture and Utilization in the Steel Industry : Challenges and Opportunities for Chemical Engineering.” CURRENT OPINION IN CHEMICAL ENGINEERING, vol. 26, 2019, pp. 81–87, doi:10.1016/j.coche.2019.09.001.

APA

De Ras, K., Van de Vijver, R., Galvita, V., Marin, G., & Van Geem, K. (2019). Carbon capture and utilization in the steel industry : challenges and opportunities for chemical engineering. CURRENT OPINION IN CHEMICAL ENGINEERING, 26, 81–87. https://doi.org/10.1016/j.coche.2019.09.001

Chicago author-date

De Ras, Kevin, Ruben Van de Vijver, Vladimir Galvita, Guy Marin, and Kevin Van Geem. 2019. “Carbon Capture and Utilization in the Steel Industry : Challenges and Opportunities for Chemical Engineering.” CURRENT OPINION IN CHEMICAL ENGINEERING 26: 81–87. https://doi.org/10.1016/j.coche.2019.09.001.

Chicago author-date (all authors)

Vancouver

De Ras K, Van de Vijver R, Galvita V, Marin G, Van Geem K. Carbon capture and utilization in the steel industry : challenges and opportunities for chemical engineering. CURRENT OPINION IN CHEMICAL ENGINEERING. 2019;26:81–7.

IEEE

[1]

K. De Ras, R. Van de Vijver, V. Galvita, G. Marin, and K. Van Geem, “Carbon capture and utilization in the steel industry : challenges and opportunities for chemical engineering,” CURRENT OPINION IN CHEMICAL ENGINEERING, vol. 26, pp. 81–87, 2019.

@article{8635595, abstract = {{The availability of green electricity, changes to the Emission Trading Scheme (ETS) system and technological breakthroughs will determine how the steel industry will evolve in the coming decades. The blast furnace (BF) technology will continue to dominate steel production in the coming decade and the only way to substantially reduce the associated CO2 emissions is to combine it with Carbon Capture and Utilization (CCU) and/or Carbon Capture and Storage (CCS). CCU options that do not require a lot of hydrogen and with high added value are logical step stones towards production of bulk chemicals and even fuels such as oxymethylene ethers. BF waste gas recycling and conversion will require a multisectoral approach creating new dependencies between the steel, energy, and chemical sectors. Energy efficient, cheap and CO2 free hydrogen production using green electricity is the ultimate solution to drive this transition. This hydrogen could on the long term also open the door to replace blast furnaces by hydrogen-based steel making. However, today it makes economically more sense to use thermally produced hydrogen by (bio)methane pyrolysis or steam reforming, potentially electrified and intensified, rather than from water electrolysis. Having novel and existing elements from the chemical engineers' toolbox such as artificial intelligence, catalysis and reaction engineering, process intensification principles and multiscale modeling and design, should bring these emerging technologies within reach by the end of the next decade.}}, author = {{De Ras, Kevin and Van de Vijver, Ruben and Galvita, Vladimir and Marin, Guy and Van Geem, Kevin}}, issn = {{2211-3398}}, journal = {{CURRENT OPINION IN CHEMICAL ENGINEERING}}, keywords = {{General Energy,POSTCOMBUSTION CO2 CAPTURE,WATER ELECTROLYSIS,RENEWABLE ENERGY,DIOXIDE CO2,HYDROGEN,METHANE,REDUCTION,FUTURE,TECHNOLOGIES,CONVERSION}}, language = {{eng}}, pages = {{81--87}}, title = {{Carbon capture and utilization in the steel industry : challenges and opportunities for chemical engineering}}, url = {{http://doi.org/10.1016/j.coche.2019.09.001}}, volume = {{26}}, year = {{2019}}, }