Multiscale optimization analysis of high strength alkali-activated concrete containing waste medical glass under exposure to carbonation and elevated temperatures
This study focused on optimizing the effect of recycled medical glass (RMG) on the performance of high-strength alkali-activated concrete (AAC) at different scales. RMG was incorporated into the AACs to substitute a portion of the precursor, followed by the addition of fine and coarse RMG to replace...
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my.uniten.dspace-363492025-03-03T15:42:02Z Multiscale optimization analysis of high strength alkali-activated concrete containing waste medical glass under exposure to carbonation and elevated temperatures Abdellatief M. Adel B. Alanazi H. Tawfik T.A. 57855303900 59197552800 56928172000 57205561464 Carbonation Compressive strength Construction Design Durability Freezing Glass Intelligent buildings Microstructure Tensile strength Thawing Alkali-activated concretes Design method Elevated temperature High-strength Medical glass Multi-scale optimization Optimization analysis Residual strength Simplex centroid design method Waste medical glass Water absorption This study focused on optimizing the effect of recycled medical glass (RMG) on the performance of high-strength alkali-activated concrete (AAC) at different scales. RMG was incorporated into the AACs to substitute a portion of the precursor, followed by the addition of fine and coarse RMG to replace a portion of the fine and coarse river sand, respectively. Thus, the effects of these variables on compressive strength, splitting strength, and water absorption using the simplex centroid design method were examined. Additionally, freezing-thawing, carbonation resistance, and residual strength at elevated temperatures of AACs were investigated. The experimental results showed that AACs had compressive strengths between 46.8 and 102.0 MPa, tensile strengths between 6.20 and 13.60 MPa, and water absorption between 2.93 and 4.82%. The optimized AACs showed a significant increment in residual strength at high temperatures as compared to the control mixture. The AAC with RMG may provide a compact microstructure with low porosity to enhance carbonation and freeze-thaw resistance. Finally, the outcomes of the ecological evaluation support the usage of RMG in high strength AAC as a sustainable building and construction material. ? 2024 The Authors Final 2025-03-03T07:42:02Z 2025-03-03T07:42:02Z 2024 Article 10.1016/j.dibe.2024.100492 2-s2.0-85197300869 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85197300869&doi=10.1016%2fj.dibe.2024.100492&partnerID=40&md5=98d0e26747a28907bab14a3930bbc0cd https://irepository.uniten.edu.my/handle/123456789/36349 19 100492 All Open Access; Hybrid Gold Open Access Elsevier Ltd Scopus |
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Carbonation Compressive strength Construction Design Durability Freezing Glass Intelligent buildings Microstructure Tensile strength Thawing Alkali-activated concretes Design method Elevated temperature High-strength Medical glass Multi-scale optimization Optimization analysis Residual strength Simplex centroid design method Waste medical glass Water absorption |
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Carbonation Compressive strength Construction Design Durability Freezing Glass Intelligent buildings Microstructure Tensile strength Thawing Alkali-activated concretes Design method Elevated temperature High-strength Medical glass Multi-scale optimization Optimization analysis Residual strength Simplex centroid design method Waste medical glass Water absorption Abdellatief M. Adel B. Alanazi H. Tawfik T.A. Multiscale optimization analysis of high strength alkali-activated concrete containing waste medical glass under exposure to carbonation and elevated temperatures |
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This study focused on optimizing the effect of recycled medical glass (RMG) on the performance of high-strength alkali-activated concrete (AAC) at different scales. RMG was incorporated into the AACs to substitute a portion of the precursor, followed by the addition of fine and coarse RMG to replace a portion of the fine and coarse river sand, respectively. Thus, the effects of these variables on compressive strength, splitting strength, and water absorption using the simplex centroid design method were examined. Additionally, freezing-thawing, carbonation resistance, and residual strength at elevated temperatures of AACs were investigated. The experimental results showed that AACs had compressive strengths between 46.8 and 102.0 MPa, tensile strengths between 6.20 and 13.60 MPa, and water absorption between 2.93 and 4.82%. The optimized AACs showed a significant increment in residual strength at high temperatures as compared to the control mixture. The AAC with RMG may provide a compact microstructure with low porosity to enhance carbonation and freeze-thaw resistance. Finally, the outcomes of the ecological evaluation support the usage of RMG in high strength AAC as a sustainable building and construction material. ? 2024 The Authors |
| author2 |
57855303900 |
| author_facet |
57855303900 Abdellatief M. Adel B. Alanazi H. Tawfik T.A. |
| format |
Article |
| author |
Abdellatief M. Adel B. Alanazi H. Tawfik T.A. |
| author_sort |
Abdellatief M. |
| title |
Multiscale optimization analysis of high strength alkali-activated concrete containing waste medical glass under exposure to carbonation and elevated temperatures |
| title_short |
Multiscale optimization analysis of high strength alkali-activated concrete containing waste medical glass under exposure to carbonation and elevated temperatures |
| title_full |
Multiscale optimization analysis of high strength alkali-activated concrete containing waste medical glass under exposure to carbonation and elevated temperatures |
| title_fullStr |
Multiscale optimization analysis of high strength alkali-activated concrete containing waste medical glass under exposure to carbonation and elevated temperatures |
| title_full_unstemmed |
Multiscale optimization analysis of high strength alkali-activated concrete containing waste medical glass under exposure to carbonation and elevated temperatures |
| title_sort |
multiscale optimization analysis of high strength alkali-activated concrete containing waste medical glass under exposure to carbonation and elevated temperatures |
| publisher |
Elsevier Ltd |
| publishDate |
2025 |
| _version_ |
1825816269576732672 |
| score |
13.244413 |