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

CEMENT Pub Date : 2024-09-20 DOI:10.1016/j.cement.2024.100117

Zengliang Yue , Yuvaraj Dhandapani , Samuel Adu-Amankwah , Susan A. Bernal

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Abstract

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 SO₄^2- 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.

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硫酸钠活化矿渣水泥浆的相变和性能

本研究评估了使用三种商用矿渣生产的 Na2SO4 活性矿渣水泥的反应动力学、相组合和微观结构演变。发现的主要反应产物是乙长石和铝硅酸钙水合物，以及结晶度较低的 SO42-插层镁-铝层双氢氧化物（LDH）相。研究结果表明，矿渣中 Al2O3 的含量本身与水泥的性能并不相关。用 Al2O3 含量较高的矿渣制成的水泥浆反应动力学速度更快，而用 Mg/Al 比率较高的矿渣制成的水泥浆在较长的固化时间内抗压强度更高，孔隙率更低。热力学模型模拟表明，硫酸盐的消耗是通过乙长石和 LDH 相的形成而发生的，从而影响了这些水泥的炉渣反应度、pH 值和孔隙率的降低。这项研究强调了矿渣成分在控制硫酸钠活化矿渣水泥浆微观结构以及性能方面的关键作用。

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