Carbon Dioxide Sequestration in Cementitious Construction Materials (2nd Ed.) Woodhead Publishing Series in Civil and Structural Engineering Series
Coordonnateurs : Pacheco-Torgal F., Shi Caijun, Palomo Angel
Carbon Dioxide Sequestration in Cementitious Construction Materials, Second Edition follows on the success of the previous edition and provides an up-to-date review on recent research developments on cementitious construction materials based on carbon dioxide storage. Brand new chapters are included on carbonation methods, such as carbon sequestration of cement pastes during pressurized CO2 curing; carbon dioxide sequestration of low-calcium fly ash via direct aqueous carbonation; increasing the efficiency of carbon dioxide sequestration through high temperature carbonation; and carbon sequestration in engineered cementitious composites. There are also several new case studies on sequestration of industrial wastes, which include carbon dioxide sequestration by direct mineralization of fly ash; the effect of direct carbonation routes of basic oxygen furnace slag on strength and hydration of blended cement paste; carbon sequestration of mine waste and utilization as a supplementary cementitious material; and carbon dioxide sequestration on masonry blocks based on industrial wastes.
1. Introduction to carbon dioxide sequestration through innovative cementitious construction materials Part One - Carbonation methods and mechanisms 2. Methods for assessing carbon dioxide absorbed by cementitious materials 3. Carbon dioxide sequestration on magnesium-based binders 4. Influence of ambient pressure on carbon sequestration of steel slag-based materials 5. Carbon sequestration in autoclaved cement pastes Part Two - Sequestration in industrial wastes 6. Carbon dioxide sequestration on steel slag 7. CO2 sequestration via mineralization of basic oxygen furnace slag 8. Carbon sequestration of mine waste and utilization as supplementary cementitious material 9. Carbon dioxide sequestration on recycled aggregates 10. Aqueous carbonation of recycled aggregates 11. Life cycle assessment of carbon dioxide sequestration Part Three - Biosequestration 12. Use of bacteria in the carbonation and self-healing of Portland cement and reactive magnesia mixes 13. Carbon sequestration of bamboo biochar mortar 14. Carbon sequestration of wood bio-concrete 15. Application of bio-inspired materials in CO2 sequestration of cementitious construction materials
Caijun Shi is a professor of civil engineering at Hunan University, China. His research interests are in the design, properties and applications of HPC/UHPC; Performance enhancement of recycled concrete aggregates; Chemically activated cementitious materials and structural design; and CO2 Sequestration in concrete materials and related products.
Angel Palomo is a professor at the Instituto de Ciencias de la Construcción Eduardo Torroja, CSIC, Spain. Dr. Palomo has been a research staff member at the IETcc since 1981 (Professor since 2009). He has vast experience in construction materials research, especially in cements and concretes, including manufacture, durability, and development of new binders and related materials. He has authored/co-authored more than 200 scientific or technical papers in high impact factor journals and has registered four patents for inventions associated with obtaining mineralized cement and alkaline binders. He has also participated in 70 research projects and research contracts and was the principal investigator in almost half of these.
- Promotes the importance of CO2? storage in carbonation of construction materials, especially reincorporation of CO2? during fabrication
- Discusses a wide range of cementitious materials with CO2? storage capabilities
- Features redesign of cementation mechanisms to utilize CO2? during fabrication
- Covers biosequestration
Date de parution : 05-2024
Ouvrage de 426 p.
15x22.8 cm
Thèmes de Carbon Dioxide Sequestration in Cementitious... :
Mots-clés :
Carbon dioxide emissions; CO2 storage; eco-efficiency; built environment; cement; concrete
