Achieving ultra-ductility exceeding 13 % and cost efficiency with rubberized alkali-activated slag-based cement-free composites

Achieving ultra-ductility exceeding 13 % and cost efficiency with rubberized alkali-activated slag-based cement-free composites

This study introduces novel ultra-ductile rubberized alkali-activated slag composites (UD-RSCs) reinforced by normal polyethylene (NPE) and selvage PE-based (SPE) fibers. Five mixtures with different sand-to-binder (s/b) and water-to-binder (w/b) ratios, as well as fiber reinforcements were designed...

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Bibliographic Details
Main Authors: Quang-Hiếu Lương, Huy Hoàng Nguyễn, Phương Hoàng Nguyễn, Se-Eon Park, Youngsang Kim, Bang Yeon Lee
Format: Article
Language:English
Published: Elsevier 2025-04-01
Series:Developments in the Built Environment
Subjects:
Alkali-activated slag
Fiber-reinforced composites
Selvage fiber
Tensile strain capacity
Cost efficiency
Online Access:http://www.sciencedirect.com/science/article/pii/S2666165925000778
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Summary:This study introduces novel ultra-ductile rubberized alkali-activated slag composites (UD-RSCs) reinforced by normal polyethylene (NPE) and selvage PE-based (SPE) fibers. Five mixtures with different sand-to-binder (s/b) and water-to-binder (w/b) ratios, as well as fiber reinforcements were designed. Then density, compressive strength, and tensile properties of UD-RSCs were measured. Mineralogy analysis was also performed to determine typical morphologies and chemical compositions of UD-RSCs. The PE fiber-reinforced UD-RSC with a sand-to-binder ratio of 0.8 showed a tensile strain capacity of up to 15.6 %, higher than the minimum extensibility of rebar. SPE fiber-reinforced UD-RSC also showed a tensile strain capacity of 13.4 %. Based on a comprehensive comparison, SPE-UD-RSC exhibited improved sustainability while maintaining high mechanical performance compared to PE-UD-RSCs and other ductile composites reinforced by recycled fibers. Through mineralogy analyses, robust fiber bridging behavior was elucidated and C-A-S-H gels were confirmed as the dominant hydration product of UD-RSCs.
ISSN:2666-1659

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