Effect of carbonization on chloride penetration in rapid repair mortar derived from solid waste-based CSA cement

Effect of carbonization on chloride penetration in rapid repair mortar derived from solid waste-based CSA cement

The development of highly corrosion-resistant rapid repair mortar (RRM) for marine concrete is of great importance, particularly given the significant role that Cl- corrosion plays in the deterioration of marine construction materials. In this work, the penetration effects of Cl- in RRM derived from...

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Bibliographic Details
Main Authors: Xiangshan Hou, Jingwei Li, Chuang Guan, Xinyan Zhang, Xujiang Wang, Yuzhong Li, Yujie Li, Wenbin Shi, Wenlong Wang
Format: Article
Language:English
Published: Elsevier 2025-12-01
Series:Case Studies in Construction Materials
Subjects:
Rapid repair mortar
Chloride ions
Carbonization
Ettringite
Hydrothermal carbon
Online Access:http://www.sciencedirect.com/science/article/pii/S2214509525007545
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Summary:The development of highly corrosion-resistant rapid repair mortar (RRM) for marine concrete is of great importance, particularly given the significant role that Cl- corrosion plays in the deterioration of marine construction materials. In this work, the penetration effects of Cl- in RRM derived from solid waste-based CSA cement was experimentally characterized. The impact of carbonization and the incorporation of hydrothermal carbon on the anti-Cl-permeation characteristics was investigated. The evolution of the mineral phase composition and microstructure of the RRM in response to Cl- corrosion was analyzed. The results showed that ettringite in RRM was transformed into an unstable Cl-ettringite with elevated Cl- concentrations, which subsequently decomposed into minerals such as zunyite. Nevertheless, ettringite adsorbs chloride onto its surface at low Cl- concentrations, thereby impeding the diffusion of Cl-. Carbonization reduced the resistance of RRM to the penetration of Cl- in two ways: firstly, ettringite is carbonized to produce minerals such as CaCO3 and CaSO4∙2 H2O, which reduces the binding capacity of RRM for Cl-; secondly, carbonization results in smaller pore spaces and higher connectivity, which enhances capillarity and facilitates the penetration of the solution to the interior. The addition of hydrothermal carbon can improve the binding capacity of RRM for Cl-, but does not prevent the carbonization process.
ISSN:2214-5095

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