Please use this identifier to cite or link to this item: https://doi.org/10.3390/polym13162750
Title: Optimisation of gbfs, fly ash, and nano-silica contents in alkali-activated mortars
Authors: Algaifi, Hassan Amer
Mustafa Mohamed, Abdeliazim
Alsuhaibani, Eyad
Shahidan, Shahiron
Alrshoudi, Fahed
Huseien, Ghasan Fahim 
Bakar, Suhaimi Abu
Keywords: Alkali-activated mortars
Fly ash
Granulated blast-furnace slag
Mechanical properties
Nano silica
Optimisation
Optimisation
Waste glass materials
Issue Date: 16-Aug-2021
Publisher: MDPI AG
Citation: Algaifi, Hassan Amer, Mustafa Mohamed, Abdeliazim, Alsuhaibani, Eyad, Shahidan, Shahiron, Alrshoudi, Fahed, Huseien, Ghasan Fahim, Bakar, Suhaimi Abu (2021-08-16). Optimisation of gbfs, fly ash, and nano-silica contents in alkali-activated mortars. Polymers 13 (16) : 2750. ScholarBank@NUS Repository. https://doi.org/10.3390/polym13162750
Rights: Attribution 4.0 International
Abstract: Although free-cement-based alkali-activated paste, mortar, and concrete have been recog-nised as sustainable and environmental-friendly materials, a considerable amount of effort is still being channeled to ascertain the best binary or ternary binders that would satisfy the requirements of strength and durability as well as environmental aspects. In this study, the mechanical properties of alkali-activated mortar (AAM) made with binary binders, involving fly ash (FA) and granulated blast-furnace slag (GBFS) as well as bottle glass waste nano-silica powder (BGWNP), were opti-mised using both experimentally and optimisation modelling through three scenarios. In the first scenario, the addition of BGWNP varied from 5% to 20%, while FA and GBFS were kept constant (30:70). In the second and third scenarios, BGWNP (5–20%) was added as the partial replacement of FA and GBFS, separately. The results show that the combination of binary binders (FA and GBFS) and BGWNP increased AAM’s strength compared to that of the control mixture for all scenarios. In addition, the findings also demonstrated that the replacement of FA by BGWNP was the most significant, while the effect of GBFS replacement by BGWNP was less significant. In particular, the highest improvement in compressive strength was recorded when FA, GBFS, and BGWNP were 61.6%, 30%, and 8.4%, respectively. Furthermore, the results of ANOVA (p values < 0.0001 and high F-values) as well as several statistical validation methods (R > 0.9, RAE < 0.1, RSE < 0.013, and RRSE < 0.116) confirmed that all the models were robust, reliable, and significant. Similarly, the data variation was found to be less than 5%, and the difference between the predicted R2 and adj. R2 was very small (<0.2), thus confirming that the proposed non-linear quadratic equations had the capability to predict for further observation. In conclusion, the use of BGWNP in AAM could act as a beneficial and sustainable strategy, not only to address environmental issues (e.g., landfill) but to also enhance strength properties. © 2021 by the authors. Licensee MDPI, Basel, Switzerland.
Source Title: Polymers
URI: https://scholarbank.nus.edu.sg/handle/10635/233663
ISSN: 2073-4360
DOI: 10.3390/polym13162750
Rights: Attribution 4.0 International
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