Advances in understanding cement hydration mechanisms

Advances in understanding cement hydration mechanisms

Progress in understanding hydration mechanisms of alite and Portland cement is reviewed. Up to the end of the induction period, dissolution rates determined by the undersaturation of the solution dominate the reaction, but, better understanding is needed about the alite solution interface. The main...

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Veröffentlicht in:Cement and concrete research 2019-10, Vol.124, p.105823, Article 105823
Hauptverfasser: Scrivener, Karen, Ouzia, Alexandre, Juilland, Patrick, Kunhi Mohamed, Aslam
Format: Artikel
Sprache:eng
Schlagworte:
Acceleration
Aluminum oxide
Cement
Cement hydration
Consumption
Deceleration
Diffusion rate
Hydration
Induction period
Later ages
Main hydration peak
Morphology
Portland cements
Tricalcium silicate
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Zusammenfassung:Progress in understanding hydration mechanisms of alite and Portland cement is reviewed. Up to the end of the induction period, dissolution rates determined by the undersaturation of the solution dominate the reaction, but, better understanding is needed about the alite solution interface. The main heat evolution peak hydration is dominated by the growth of outer C-S-H with a spiky or “needle” like morphology. Growth is rapid over several hours (acceleration period) and then slows (deceleration period). At later ages the consumption of water and lack of water filled pores above about 10 nm, along with the consumption of anhydrous material are major factors leading to the continual reduction in the rate of reaction. There is no evidence that diffusion becomes the rate controlling mechanism even at this stage. The microstructure of cement differs significantly from that of alite, largely due to the influence of alumina on C-S-H growth and distribution.
ISSN:0008-8846
1873-3948
DOI:10.1016/j.cemconres.2019.105823