Great News | Journal of Building Material Science Receives First CiteScore of 0.5!
2025-06-12
Physicochemical and Thermomechanical Performance of Eco-Friendly Unfired Clay-Biopolymer Composite Bricks
Authors
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Rachid Et-Tanteny
Laboratory of Computer Science and Interdisciplinary Physics (LIPI), ENS-Fez, Sidi Mohamed Ben Abdellah University, Fez P.O. Box 5206, Morocco
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Imad Manssouri
Team of Innovative Research and Applied Physics, Faculty of Sciences, Moulay Ismail University, Meknes P.O. Box 11201, Morocco
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Aboubakr Bouayad
Laboratory of Engineering Sciences and Professions, ENSAM, Moulay Ismaïl University, Meknes P.O. Box 15290, Morocco
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Houssame Limami
Laboratory of Sustainable Energy Materials, Al Akhawayn University, Ifrane P.O. Box 104, Morocco
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Amine Azzouzi
Team of Innovative Research and Applied Physics, Faculty of Sciences, Moulay Ismail University, Meknes P.O. Box 11201, Morocco
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Bouchta El Amrani
Laboratory of Computer Science and Interdisciplinary Physics (LIPI), ENS-Fez, Sidi Mohamed Ben Abdellah University, Fez P.O. Box 5206, Morocco
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Karim El Khadiri
Laboratory of Computer Science and Interdisciplinary Physics (LIPI), ENS-Fez, Sidi Mohamed Ben Abdellah University, Fez P.O. Box 5206, Morocco
DOI:
https://doi.org/10.30564/jbms.v7i3.7994Abstract
The rapid growth of the global population, coupled with increasing pollution levels, highlights the urgent need for sustainable and eco-friendly construction materials, such as unfired clay bricks. However, their widespread adoption remains limited due to certain performance drawbacks, particularly in thermal insulation, a critical factor in addressing climate change challenges. In this study, a plant-based waste-derived biopolymer was incorporated into unfired clay bricks to enhance their physicochemical and thermomechanical properties. The biopolymer was added at six different weight fractions (0%, 1%, 3%, 7%, 15%, and 20%) to systematically evaluate its impact on bulk density, porosity, capillary water absorption, thermal conductivity, specific heat capacity, and compressive strength. The results revealed a gradual decrease in porosity as the biopolymer content increased, leading to a 41% improvement in thermal conductivity at 20 wt%. However, the optimal balance between thermal efficiency and compressive strength was achieved at 7 wt% biopolymer; this result has been verified through a combination of experimental methods and modeling. Additionally, TRNSYS simulations confirmed the enhanced thermal performance, demonstrating a 9.74% increase in time lag and a 16% reduction in decrement factor, both of which contribute to optimizing building energy efficiency. Overall, this approach not only helps reduce environmental pollution but also enhances insulation capacity while lowering heating and cooling demands, thereby improving overall building performance. Biopolymer-reinforced unfired clay bricks thus represent a promising solution for advancing a low-carbon and sustainable construction industry, aligning with the United Nations Sustainable Development Goals (SDGs) for climate change mitigation and responsible resource management.
Keywords:
Clay–Polymer Composites; Sustainable Construction Materials; Climate Change Adaptation; Waste-Derived Additives; Circular Economy Strategies; Low-Carbon Building TechnologiesReferences
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Et-Tanteny, R., Manssouri, I., Bouayad, A., Limami, H., Azzouzi, A., El Amrani, B., & El Khadiri, K. (2025). Physicochemical and Thermomechanical Performance of Eco-Friendly Unfired Clay-Biopolymer Composite Bricks. Journal of Building Material Science, 7(3), 166–182. https://doi.org/10.30564/jbms.v7i3.7994
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Copyright © 2025 Rachid Et-Tanteny, Imad Manssouri, Aboubakr Bouayad, Houssame Limami, Amine Azzouzi, Bouchta El Amrani, Karim El Khadiri
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