Phase evolution and performance of sodium sulfate-activated slag cement pastes

Phase evolution and performance of sodium sulfate-activated slag cement pastes

This study evaluates the reaction kinetics, phase assemblage, and microstructure evolution of Na2SO4-activated slag cements produced with three commercial slags. The main reaction products identified are ettringite and calcium aluminosilicate hydrates, alongside a poorly crystalline SO42- intercalat...

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Bibliographic Details
Main Authors: Zengliang Yue, Yuvaraj Dhandapani, Samuel Adu-Amankwah, Susan A. Bernal
Format: Article
Language:English
Published: Elsevier 2024-12-01
Series:Cement
Subjects:
Blast furnace slag
Alkali-activated cements
Sodium sulfate
Microstructure
Thermodynamic modelling
Compressive strength
Online Access:http://www.sciencedirect.com/science/article/pii/S2666549224000264
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Summary:This study evaluates the reaction kinetics, phase assemblage, and microstructure evolution of Na2SO4-activated slag cements produced with three commercial slags. The main reaction products identified are ettringite and calcium aluminosilicate hydrates, alongside a poorly crystalline SO42- intercalated Mg-Al-layered double hydroxide (LDH) phase. Results revealed that the Al2O3 slag content alone does not correlate with the cement performance. While pastes made with a higher Al2O3 content slag exhibit faster reaction kinetics, those made with a slag with a higher Mg/Al ratio developed superior compressive strength and reduced porosity over extended curing periods. Thermodynamic modelling simulations indicate that sulfate consumption occurs via ettringite and LDH phase formation, influencing the slag reaction degree, pH value, and porosity reduction in these cements. This research highlights the critical role of slag composition in controlling microstructure and, consequently, performance of sodium sulfate activated slag cement pastes.
ISSN:2666-5492

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