Carbon dioxide sequestration in cementitious materials: A review of techniques, material performance, and environmental impact

The release of carbon dioxide (CO2) into the earth's atmosphere is a substantial global environmental concern that arises from the processes of industrialization and urbanization. The increase in atmospheric CO2 concentrations has resulted in the phenomenon of global warming and subsequent alte...

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Published inJournal of CO2 utilization Vol. 83; p. 102812
Main Authors Ahmed, Omer, Ahmad, Shamsad, Adekunle, Saheed K.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.05.2024
Elsevier
Subjects
Carbon footprint
Cement
CO2 utilization
Concrete
Mineral carbonation
Solid wastes
LD steel slag
Mth
C-S-H
EAFRS
HFA
HM
CO2
GWP-E
PCFA
GGBF slag
SS
ACC
GWP
BOF slag
CSW
EAF slag
Solid wastes
AFm
CM
LCA
Carbon footprint
C3A
SCMs
RCA
ACT
Mineral carbonation
CCU
NC
Mc
Cement
CO2 utilization
Concrete
FA
MCO2
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Summary:The release of carbon dioxide (CO2) into the earth's atmosphere is a substantial global environmental concern that arises from the processes of industrialization and urbanization. The increase in atmospheric CO2 concentrations has resulted in the phenomenon of global warming and subsequent alterations in climate patterns. Accelerated CO2 sequestration in cementitious materials is currently the subject of extensive research as a highly efficacious approach to mitigating the carbon footprint of the concrete industry. The sequestration procedure entails the transformation of gaseous CO2 into carbonate minerals. The review presented in this paper outlines the most recent carbonation (i.e., CO2 sequestration) techniques, such as mineral carbonation, accelerated CO2 curing (ACC), pre-carbonation, and carbonation mixing, that have been recently explored. The potential of mineral carbonation of industrial wastes and the advantages of their incorporation in the concrete matrix is investigated. Carbonation technologies and their effect on the performance of cementitious composites are reported. Information on life cycle assessment are also included to evaluate the environmental impact associated with the production of carbonated materials. Various commercialized CO2 utilization technologies in construction sector, such as CarbonCure, Solidia, Carbstone, Calera, and Carbon8 are reviewed. Moreover, this review offers a thorough insight into the carbonation technologies, evaluating their advantages, limitations, and the existing gaps in research. •Various carbonation techniques for CO2 incorporation in concrete comprehensively reviewed.•Limitations and research gaps of carbonation technologies are discussed.•Potentials uses of CO2-mineralized industrial wastes in the concrete discussed.•Commercial CO2 utilization technologies in the construction sector identified.•LCA of carbonated materials to ensure sustainable production practices presented.
ISSN:2212-9820
2212-9839
DOI:10.1016/j.jcou.2024.102812