Development of eco-friendly alkali-activated nanocomposites comprising micro-fibers at ambient curing conditions

Geopolymers (GOPL) can play a vital role in the sustainability of concrete construction. The addition of nanoparticles and micro-fibers to GOPL can improve the mechanical and microstructural performance by densifying the matrix and providing the bridging effect against the internal cracking mechanis...

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Bibliographic Details
Published in:Case Studies in Construction Materials 2022-12, Vol.17, p.e01540, Article e01540
Main Authors: Raza, Ali, Alashker, Yasser, Azab, Marc, Khan, Qaiser uz Zaman, Abdallah, Mirvat, Barakat, Osama, Elhadi, Khaled Mohamed
Format: Article
Language:English
Subjects:
Basalt fiber
Coal ash
Geopolymer
Hardness
Nano-sodium oxide
Scanning electron microscope
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Summary:Geopolymers (GOPL) can play a vital role in the sustainability of concrete construction. The addition of nanoparticles and micro-fibers to GOPL can improve the mechanical and microstructural performance by densifying the matrix and providing the bridging effect against the internal cracking mechanism. Therefore, an extensive investigation on the improvement of the various characteristics of the GOPL is required to make it feasible for practical applications. Moreover, the combined effect of nanoparticles and micro-fibers on various features of GOPL needs further insights. This study investigates the microstructural, mechanical, fracture, and toughness performance of micro-basalt fiber (MBF)-reinforced coal ash-made GOPL using different proportions of nano-sodium oxide at ambient curing conditions. The percentage of nano-sodium oxide examined in the present study varied from 0% to 4% by weight. The MBF amount is kept the same for all fabricated samples at 0.5% by weight. Scanning electron microscopy is used for assessing the microstructural cracking and failure behavior of GOPL pastes. The findings of the present study divulged that the usage of 3% nano-sodium oxide in MBF-reinforced GOPL mix presented the highest increase of 29%, 55%, 24%, and 60% for the compression strength, flexure strength, fracture toughness, and impact strength, respectively. Further increase in the content of nano-sodium oxide prompted the agglomeration of nanoparticles leading to a reduction in the performance of the GOPL. The outcomes of scanned electron microscopy delineated that the addition of nano-sodium oxide refined the interfacial regions and promoted the polymerization process of the GOPL which enriched the microstructure and fabricated a highly densified GOPL paste. •Different geopolymer nanocomposites were manufactured with nanoparticles.•Effect of micro-basalt fibers and nano Na2O was examined.•Various mechanical and fracture properties of geopolymer were assessed.•Improvement in mechanical performance of geopolymer was observed due to nanoparticles.
ISSN:2214-5095
2214-5095
DOI:10.1016/j.cscm.2022.e01540