Reactive MgO as alkaline activator in slag/fly ash-based strain-hardening cementitious composites for cementless marine engineering

Reactive MgO as alkaline activator in slag/fly ash-based strain-hardening cementitious composites for cementless marine engineering

A novel category of polyethylene (PE) fiber-reinforced strain-hardening reactive MgO-activated slag/fly ash composites (SH-RMGC) with ultra-high ductility is developed in this study. The developed SH-RMGC carried a compressive strength of 17–50 MPa, a tensile strength of 3–8 MPa, and a tensile strai...

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Bibliographic Details
Main Authors: Long Liang, Yunqi Jiang, Xudong Tang, Jie Xiao, Lingfei Liu
Format: Article
Language:English
Published: Elsevier 2025-12-01
Series:Case Studies in Construction Materials
Subjects:
Strain-hardening
Reactive MgO
Slag/fly ash
Ultra-high tensile ductility
Material sustainability
Online Access:http://www.sciencedirect.com/science/article/pii/S2214509525010022
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Summary:A novel category of polyethylene (PE) fiber-reinforced strain-hardening reactive MgO-activated slag/fly ash composites (SH-RMGC) with ultra-high ductility is developed in this study. The developed SH-RMGC carried a compressive strength of 17–50 MPa, a tensile strength of 3–8 MPa, and a tensile strain capacity exceeding 7 %. Results showed that a lower water-to-binder (w/b) ratio resulted in higher compressive strength and tensile strength. With increasing MgO content, the matrix fracture toughness, compressive strength, tensile strength, and strain energy density of SH-RMGC increased, while the ultra-high tensile strain capacity remained. The most robust strain-hardening performance was recorded in SH-RMGC with 20 % MgO. The mechanism of ultra-high tensile ductility was illustrated based on a micromechanical model. The impacts of MgO contents on the chemical characterization of matrix were investigated to understand the gained mechanical performance of SH-RMGC. The primary hydration products of matrix were C-A-S-H, brucite, and hydrotalcite-like, and higher MgO content led to higher hydration reaction degree. The reduced Al/Si ratio of C-A-S-H and the enhanced Mg/Al ratio of hydrotalcite-like were found with the addition of MgO, resulting in the refined microstructure with reduced porosity. Additionally, the developed SH-RMGC showed better material sustainability than the existing alkali-activated/cement-based counterpart. This advanced material holds the potential for extended application in marine engineering.
ISSN:2214-5095

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