Improving Cement Paste Performance with Temperature-Sensitive PNIPAM Hydrogel Particles

Dr. Li, Wei and Prof. Chen, Wang (2024) Improving Cement Paste Performance with Temperature-Sensitive PNIPAM Hydrogel Particles. Innovative: International Multi-disciplinary Journal of Applied Technology, 2 (6). pp. 157-166. ISSN 2995-486X

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Abstract

In the quest to advance construction materials, enhancing the performance of cement paste is critical, particularly in addressing challenges related to workability and shrinkage. This study investigates the potential of temperature-sensitive poly(N-isopropylacrylamide) (PNIPAM) hydrogel particles to significantly improve the properties of cement paste. PNIPAM hydrogels exhibit unique thermo-responsive behavior, transitioning at a specific temperature, which allows them to modulate water retention and release within the cement matrix. Our research outlines the synthesis and functionalization of PNIPAM hydrogel particles to ensure compatibility with cement paste. Experimental evaluations reveal that the incorporation of these hydrogels markedly enhances workability, resulting in improved fluidity and ease of mixing without compromising setting time. Furthermore, PNIPAM hydrogels demonstrate a notable reduction in both plastic and drying shrinkage, addressing a major cause of structural integrity issues in concrete. The study delves into the underlying mechanisms by which PNIPAM hydrogels interact with the cement matrix, optimizing water management and reducing internal stresses. Comparative analyses with traditional additives underscore the superior performance of PNIPAM hydrogels. Practical applications in various construction scenarios are explored, highlighting economic and environmental benefits. The findings of this research suggest that temperature-sensitive PNIPAM hydrogel particles present a promising solution for enhancing cement paste performance, offering significant advantages in terms of workability and shrinkage reduction. This innovative approach holds potential for widespread adoption in the construction industry, paving the way for more durable and sustainable concrete structures. Further research is encouraged to refine hydrogel formulations and explore long-term performance in diverse environmental conditions.

Item Type: Article
Subjects: Q Science > Q Science (General)
Divisions: Postgraduate > Master's of Islamic Education
Depositing User: Journal Editor
Date Deposited: 15 Aug 2024 04:35
Last Modified: 15 Aug 2024 04:35
URI: http://eprints.umsida.ac.id/id/eprint/13952

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