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The Effects of Combined Use of Sodium Citrate and PCE Plasticizer on Microstructure and Properties of Binary OPC-CAC Binder

This study examines the impact of sodium citrate and a plasticizing additive, along with their sequential introduction into a cement slurry or concrete mix, on the heat evolution of the cement slurry, the microstructure, phase composition of the cement paste, and the compressive strength of fine-gra...

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Published in:	Materials 2024-12, Vol.17 (23), p.5901
Main Authors:	Shvetsova, Victoria, Soloviev, Vadim, Matiushin, Evgenii, Erofeev, Vladimir
Format:	Article
Language:	English
Subjects:	Acids Additives Adsorption Aluminous cements Calcium aluminate Calcium compounds Cement Cement hydration Cement paste Compressive strength Concrete Corrosion Corrosion inhibitors Dicalcium silicate Energy consumption Evolution Hydration Microstructure Phase composition Portland cements Precipitation Setting (hardening) Silicates Slurries Sodium Sodium citrate Tricalcium aluminate Tricalcium silicate
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creator	Shvetsova, Victoria Soloviev, Vadim Matiushin, Evgenii Erofeev, Vladimir
description	This study examines the impact of sodium citrate and a plasticizing additive, along with their sequential introduction into a cement slurry or concrete mix, on the heat evolution of the cement slurry, the microstructure, phase composition of the cement paste, and the compressive strength of fine-grained concrete. The binder used in this research was a blended binder consisting of 90% Portland cement and 10% calcium aluminate cement. This type of binder is characterized by an increased heat evolution and accelerated setting time. The addition of sodium citrate at 5% of the binder mass alters the phase composition of newly formed compounds by increasing the quantity of AFt and AFm phases. The presence of sodium citrate significantly delays the hydration process of tricalcium silicate by a factor of 3.3. Initially, it accelerates belite hydration by 31.6%, but subsequently slows it down, with a retardation of 43.4% observed at 28 days. During the hardening process, the hydration of tricalcium aluminate and tetracalcium aluminoferrite is accelerated throughout the hardening process, with the maximum acceleration occurring within the first 24 h. During the first 24 h of hydration, the dissolution rates of tricalcium aluminate and tetracalcium aluminoferrite were 40.7% and 75% faster, respectively. Sodium citrate enhances heat evolution during the initial 24 h by up to 4.3 times and reduces the induction period by up to 5 times. Furthermore, sodium citrate promotes early strength development during the initial curing period, enhancing compressive strength by up to 6.4 times compared to the reference composition.
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source	Publicly Available Content Database; PubMed Central; Free Full-Text Journals in Chemistry
subjects	Acids Additives Adsorption Aluminous cements Calcium aluminate Calcium compounds Cement Cement hydration Cement paste Compressive strength Concrete Corrosion Corrosion inhibitors Dicalcium silicate Energy consumption Evolution Hydration Microstructure Phase composition Portland cements Precipitation Setting (hardening) Silicates Slurries Sodium Sodium citrate Tricalcium aluminate Tricalcium silicate
title	The Effects of Combined Use of Sodium Citrate and PCE Plasticizer on Microstructure and Properties of Binary OPC-CAC Binder
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