LAPSE:2023.13087
Published Article
LAPSE:2023.13087
CO2 Mineralization Methods in Cement and Concrete Industry
February 28, 2023
Abstract
Production of Portland clinker is inherently associated with CO2 emissions originating from limestone decomposition, the irreplaceable large-scale source of calcium oxide needed. Besides carbon capture and storage, CO2 mineralization is the only lever left to reduce these process emissions. CO2 mineralization is a reversal reaction to clinker production—CO2 is bound into stable carbonates in an exothermic process. It can be applied in several environmentally and economically favorable ways at different stages of clinker, cement and concrete life cycle. These possibilities are assessed and discussed in this contribution. The results demonstrate that when combined with concrete recycling, the complete circularity of all its constituents, including the process CO2 emissions from the clinker, can be achieved and the overall related CO2 intensity significantly reduced.
Production of Portland clinker is inherently associated with CO2 emissions originating from limestone decomposition, the irreplaceable large-scale source of calcium oxide needed. Besides carbon capture and storage, CO2 mineralization is the only lever left to reduce these process emissions. CO2 mineralization is a reversal reaction to clinker production—CO2 is bound into stable carbonates in an exothermic process. It can be applied in several environmentally and economically favorable ways at different stages of clinker, cement and concrete life cycle. These possibilities are assessed and discussed in this contribution. The results demonstrate that when combined with concrete recycling, the complete circularity of all its constituents, including the process CO2 emissions from the clinker, can be achieved and the overall related CO2 intensity significantly reduced.
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Keywords
carbon neutrality, carbonation, circular economy, recycled aggregates, recycling, supplementary cementitious material
Subject
Suggested Citation
Zajac M, Skocek J, Ben Haha M, Deja J. CO2 Mineralization Methods in Cement and Concrete Industry. (2023). LAPSE:2023.13087
Author Affiliations
Zajac M: HeidelbergCement AG, Global R&D, Oberklamweg 2-4, 69181 Leimen, Germany
Skocek J: HeidelbergCement AG, Global R&D, Oberklamweg 2-4, 69181 Leimen, Germany
Ben Haha M: HeidelbergCement AG, Global R&D, Oberklamweg 2-4, 69181 Leimen, Germany
Deja J: Department of Building Materials Technology, Faculty of Material Science and Ceramics, AGH University of Science and Technology, a. Mickiewicza 30, 30-059 Kraków, Poland [ORCID]
Skocek J: HeidelbergCement AG, Global R&D, Oberklamweg 2-4, 69181 Leimen, Germany
Ben Haha M: HeidelbergCement AG, Global R&D, Oberklamweg 2-4, 69181 Leimen, Germany
Deja J: Department of Building Materials Technology, Faculty of Material Science and Ceramics, AGH University of Science and Technology, a. Mickiewicza 30, 30-059 Kraków, Poland [ORCID]
Journal Name
Energies
Volume
15
Issue
10
First Page
3597
Year
2022
Publication Date
2022-05-14
ISSN
1996-1073
Version Comments
Original Submission
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PII: en15103597, Publication Type: Review
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LAPSE:2023.13087
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https://doi.org/10.3390/en15103597
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Feb 28, 2023
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