Steklo i Keramika (Glass and Ceramics). Monthly scientific, technical and industrial journal

 

ISSN 0131-9582 (Online)

THE ACTIVITY OF CEMENT?S COMPOUNDS IN CO2-HYDRATION HARDENING CONDITIONS FROM THE THERMODYNAMIC POINT OF VIEW

Details
Hits: 186
Autors:

Sivkov S. P. , Korchunov I. V. , Potapova E. N. , Dmitrieva E. A. , Klimenko N. N.

  • Continuous numbering: 1137
  • Pages: 34-43
  • Share:

Heading: Not-set

It was found that almost all the studied compounds could be carbonized under the influence of dry or wet carbon dioxide with the formation of calcium or magnesium carbonates. The equilibrium partial pressure of carbon dioxide or the equilibrium activity of the carbonate ion methods were used to evaluate carbonation reactions possibility. The activity of some minerals in carbonation reactions significantly exceeds the activity of the wollastonite and rankinite , which are used in Solidia?s clinker technolohy.

Sergey P. Sivkov – Candidate of technical sciences, Professor of the Department of Chemical Technology of Composite and Binding materials, Moscow, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it..
Ivan V. Korchunov – assistant of the Department of Chemical Technology of Composite and Binding materials, Moscow, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it..
Ekaterina N. Potapova – doctor of technical sciences, Associate professor of the Department of Chemical Technology of Composite and Binding materials, Moscow, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it..
Ekaterina A. Dmitrieva – assistant of the Department of Chemical Technology of Composite and Binding materials, Moscow, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it..
Natalia N. Klimenko – Candidate of Technical Sciences, Associate Professor of the Department of Chemical Technology of Glass and Metals, Moscow, Russia. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it..

1. Xia K., Yue Gu, Linhua Jiang, et al. Carbonation Resistance of Surface Protective Materials Modified with Hybrid NanoSiO2 // Coatings. 2021. V. 11, No. 3. P. 269.
2. Zhan B. J., Xuan D., Poon C., Shi C. Mechanism for rapid hardening of cement pastes under coupled CO2-water curing regime // Cement and Concrete Composites. 2019. V. 97. P. 78 – 88.
3. Fang Y., Chang J. Rapid hardening ?-C2S mineral and microstructure changes activated by accelerated carbonation curing // Journal of Thermal Analysis and Calorimetry. 2017. V. 129, No. 2. P. 681 – 689.
4. Korchunov I. V., Potapova E. N. Phase composition of CO2-hardened cement in the presence of chloride ions // Materials Today: Proceedings. 2021. V. 38. P. 1963 – 1967.
5. Meyer V., de Cristofaro N., Bryant J., Sahu S. Solidia Cement an Example of Carbon Capture and Utilisation // Key Engineering Materials. 2018. V. 761. P. 197 – 203.
6. Xian X., Zhang D., Shao Y. Flue gas carbonation curing of cement paste and concrete at ambient pressure // Journal of Cleaner Production. 2021. V. 313. P. 127943.
7. Wang L., Chen L., Provis J. L., et al. Accelerated carbonation of reactive MgO and Portland cement blends under flowing CO2 gas // Cement and Concrete Compo-sites. 2020. V. 106. P. 103489.
8. Wang L., Chen L., Tsang D. C. W., et al. Biochar as green additives in cement-based composites with carbon dioxide curing // Journal of Cleaner Production. 2020. V. 258. P. 120678.
9. Lin R. S., Wang Xiao-Yong, Yi-han. Effects of cement types and addition of quartz and limestone on the normal and carbonation curing of cement paste // Construction and Building Materials. 2021. V. 305. P. 124799.
10. Zhang D., Li V. C., Ellis B. R. Optimal pre-hydration age for CO2 sequestration through Portland cement carbonation // ACS Sustainable Chemistry & Engineering. 2018. V. 6, Is. 12. P. 15976 – 15981.
11. Lippiatt N., Ling T. C., Eggermont S. Combining hydration and carbonation of cement using super-saturated aqueous CO2 solution // Construction and Building Materials. 2019. V. 229. P. 116825.
12. Junior A. N., Filho R. D. T., Fairbairn E. M. R., Dweck J. CO2 sequestration by high initial strength Portland cement pastes // Journal of thermal analysis and calorimetry. 2013. V. 113, Is. 3. P. 1577 – 1584.
13. Siddique S., Naqi A., Jang J. G. Influence of water to cement ratio on CO2 uptake capacity of belite-rich cement upon exposure to carbonation curing // Cement and Concrete Composites. 2020. V. 111. P. 103616.
14. Rostami V., Shao Y., Boyd A. J. Microstructure of cement paste subject to early carbonation curing // Cement and Concrete Research. 2012. V. 42, Is. 1. P. 186 – 193.
15. Jang J. G., Lee H. K. Microstructural densification and CO2 uptake promoted by the carbonation curing of belite-rich Portland cement // Cement and Concrete Research. 2016. V. 82. P. 50 – 57.
16. Ib??ez J., Llu?s Art?s, Ramon Cusc?, et al. Hydration and carbonation of monoclinic C2S and C3S studied by Raman spectroscopy // Journal of Raman Spectroscopy: An International Journal for Original Work in all Aspects of Raman Spectroscopy, Including Higher Order Processes, and also Brillouin and Rayleigh Scattering. 2007. V. 38, Is. 1. P. 61 – 67.
17. Solidia. Solutions. URL: https://www.solidiatech. com/solutions.html (дата обращения: 13.12.2021).
18. Solidia Life Project. URL: https://www.solid-life.eu/ (дата обращения: 13.12.2021).
19. Бабушкин В. И., Матвеев Г. М., Мчедлов-Петросян О. П. Термодинамика силикатов. М.: Строй-издат, 1986. 408 с.
20. Lottenbach B., Kulik D. A., Matschei T., et al. Cemdata18: A chemical thermodynamic database for hydrated Portland cements and alkali-activated materials // Cement and Concrete Research. 2018. V. 115. P. 472 – 506.
21. Matschei T., Lothenbach B., Glasser F. P. Thermodynamic properties of Portland cement hydrates in the system CaO–Al2O3–SiO2–CaSO4–CaCO3–H2O // Cement and Concrete Research. 2007. V. 37, Is. 10. P. 1379 – 1410.
22. Parron-Rubio M. E., Perez-Garcia F., Gonzalez-Herrera A., et al. Slag substitution as a cementing material in concrete: Mechanical, physical and environmental properties // Materials. 2019. V. 12, Is. 18. P. 2845.
23. Korchunov I. V., Dmitrieva E. A., Potapova E. N. Structural features of a cement matrix modified with additives of sedimentary origin // Materials Science and Engineering. 2021. V. 1083, Is. 1. P. 012033

The article can be purchased
electronic!

PDF format

500 руб

DOI: 10.14489/glc.2022.09.pp.034-043
Article type: Research Article
Make a request

Keywords

cement?s carbonation, Solidia cement, carbonate hardening, carbon dioxide, carbonation of slag, blast furnace slag.

Use the reference below to cite the publication

Sivkov S. P., Korchunov I. V., Potapova E. N., Dmitrieva E. A., Klimenko N. N. The activity of cement?s compounds in CO2-hydration hardening conditions from the thermodynamic point of view. Steklo i keramika. 2022:95(9):34-43. (in Russ). DOI: 10.14489/glc.2022.09.pp.034-043

Баннер снизу

Editor-in-chief

Lyudmila Vladimirovna Sokolova