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Influence of elevated temperatures on the mechanical behavior of one-part coal ash geopolymer concrete with sodium metasilicate pentahydrate and sodium metasilicate anhydrous as alkaline activators

Geopolymers can be synthesized through either a one-part or two-part combination methodology. The aluminosilicate precursor is blended with an alkaline activator solution in the two-part mixture. Conversely, the one-part mixture technique incorporates water directly into the dry composite comprising...

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Main Authors: Samadi M., Wong L.S., Murali G., Lim N.H.A.S., Ayeni I.S.
Other Authors: 55915984400
Format: Article
Published: Elsevier Ltd 2025
Subjects:
Aluminosilicates
Ash handling
Ashes
Coal ash
Concrete mixtures
Deterioration
Fly ash
Geopolymers
Inorganic polymers
Microstructure
Sodium compounds
Alkaline activators
Concrete specimens
Elevated temperature
Geopolymer concrete
One parts
One-part coal ash geopolymer concrete
Pentahydrates
Sodium metasilicate
Sodium metasilicate anhydrous
Sodium metasilicate pentahydrate
Compressive strength
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spelling my.uniten.dspace-364102025-03-03T15:42:17Z Influence of elevated temperatures on the mechanical behavior of one-part coal ash geopolymer concrete with sodium metasilicate pentahydrate and sodium metasilicate anhydrous as alkaline activators Samadi M. Wong L.S. Murali G. Lim N.H.A.S. Ayeni I.S. 55915984400 55504782500 57203952839 58788283900 58068214400 Aluminosilicates Ash handling Ashes Coal ash Concrete mixtures Deterioration Fly ash Geopolymers Inorganic polymers Microstructure Sodium compounds Alkaline activators Concrete specimens Elevated temperature Geopolymer concrete One parts One-part coal ash geopolymer concrete Pentahydrates Sodium metasilicate Sodium metasilicate anhydrous Sodium metasilicate pentahydrate Compressive strength Geopolymers can be synthesized through either a one-part or two-part combination methodology. The aluminosilicate precursor is blended with an alkaline activator solution in the two-part mixture. Conversely, the one-part mixture technique incorporates water directly into the dry composite comprising the aluminosilicate precursor and solid activator. Using one-part geopolymer concrete (OPGC) stands out as a beacon of sustainability, presenting a compelling alternative to conventional cement concrete in construction projects. A noticeable gap exists in the extant literature on investigations on the response of OPGC when subjected to elevated temperatures. The study aims to evaluate the effect of elevated temperatures on the mechanical behavior of OPGC. Sodium metasilicate pentahydrate (SMP) and sodium metasilicate anhydrous (SMA) are the two types of one-part alkaline activators used to make OPGC. Fly ash was applied as a precursor, and bottom ash was varied from 25 % to 100 % as a substitute for sand in the mix designs of the OPGC specimens. The concrete specimens were characterized by their workability, compressive strength, microstructures, mineralogical properties, and thermal stability. The results revealed that OPGC specimens with SMP and SMA activators containing bottom ash, exposed to 100 �C, exhibited increased compressive strength by 7.31 % and 39.09 %, respectively, compared to those exposed to 30 �C. This trend persisted, with the highest enhancements observed at 200 �C, reaching 37.62 % and 72.39 % for SMP and SMA, respectively. However, compressive strength declined at higher temperatures, with the most significant drop occurring at 800 �C. X-ray Diffraction results and microstructural analysis confirmed that the optimized geopolymer concrete is characterized by a binding product in Sodium Aluminosilicate Hydrate (N-A-S-H) gels, forming a robust three-dimensional geopolymer network. This behaviour implies a high level of toughness for the optimized geopolymer concrete. The study underscored the importance of comprehending the bonding mechanism of geopolymer concrete activated with SMP and SMA against high temperatures, as it clarifies the scientific underpinnings of its thermal resilience and resistance to deterioration, thus guiding the advancement of durable and eco-friendly construction materials. ? 2024 Elsevier Ltd Final 2025-03-03T07:42:17Z 2025-03-03T07:42:17Z 2024 Article 10.1016/j.jobe.2024.109692 2-s2.0-85193906095 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85193906095&doi=10.1016%2fj.jobe.2024.109692&partnerID=40&md5=21dea40ffb570da3b019840c2ec85e5b https://irepository.uniten.edu.my/handle/123456789/36410 91 109692 Elsevier Ltd Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Aluminosilicates
Ash handling
Ashes
Coal ash
Concrete mixtures
Deterioration
Fly ash
Geopolymers
Inorganic polymers
Microstructure
Sodium compounds
Alkaline activators
Concrete specimens
Elevated temperature
Geopolymer concrete
One parts
One-part coal ash geopolymer concrete
Pentahydrates
Sodium metasilicate
Sodium metasilicate anhydrous
Sodium metasilicate pentahydrate
Compressive strength
spellingShingle Aluminosilicates
Ash handling
Ashes
Coal ash
Concrete mixtures
Deterioration
Fly ash
Geopolymers
Inorganic polymers
Microstructure
Sodium compounds
Alkaline activators
Concrete specimens
Elevated temperature
Geopolymer concrete
One parts
One-part coal ash geopolymer concrete
Pentahydrates
Sodium metasilicate
Sodium metasilicate anhydrous
Sodium metasilicate pentahydrate
Compressive strength
Samadi M.
Wong L.S.
Murali G.
Lim N.H.A.S.
Ayeni I.S.
Influence of elevated temperatures on the mechanical behavior of one-part coal ash geopolymer concrete with sodium metasilicate pentahydrate and sodium metasilicate anhydrous as alkaline activators
description Geopolymers can be synthesized through either a one-part or two-part combination methodology. The aluminosilicate precursor is blended with an alkaline activator solution in the two-part mixture. Conversely, the one-part mixture technique incorporates water directly into the dry composite comprising the aluminosilicate precursor and solid activator. Using one-part geopolymer concrete (OPGC) stands out as a beacon of sustainability, presenting a compelling alternative to conventional cement concrete in construction projects. A noticeable gap exists in the extant literature on investigations on the response of OPGC when subjected to elevated temperatures. The study aims to evaluate the effect of elevated temperatures on the mechanical behavior of OPGC. Sodium metasilicate pentahydrate (SMP) and sodium metasilicate anhydrous (SMA) are the two types of one-part alkaline activators used to make OPGC. Fly ash was applied as a precursor, and bottom ash was varied from 25 % to 100 % as a substitute for sand in the mix designs of the OPGC specimens. The concrete specimens were characterized by their workability, compressive strength, microstructures, mineralogical properties, and thermal stability. The results revealed that OPGC specimens with SMP and SMA activators containing bottom ash, exposed to 100 �C, exhibited increased compressive strength by 7.31 % and 39.09 %, respectively, compared to those exposed to 30 �C. This trend persisted, with the highest enhancements observed at 200 �C, reaching 37.62 % and 72.39 % for SMP and SMA, respectively. However, compressive strength declined at higher temperatures, with the most significant drop occurring at 800 �C. X-ray Diffraction results and microstructural analysis confirmed that the optimized geopolymer concrete is characterized by a binding product in Sodium Aluminosilicate Hydrate (N-A-S-H) gels, forming a robust three-dimensional geopolymer network. This behaviour implies a high level of toughness for the optimized geopolymer concrete. The study underscored the importance of comprehending the bonding mechanism of geopolymer concrete activated with SMP and SMA against high temperatures, as it clarifies the scientific underpinnings of its thermal resilience and resistance to deterioration, thus guiding the advancement of durable and eco-friendly construction materials. ? 2024 Elsevier Ltd
author2 55915984400
author_facet 55915984400
Samadi M.
Wong L.S.
Murali G.
Lim N.H.A.S.
Ayeni I.S.
format Article
author Samadi M.
Wong L.S.
Murali G.
Lim N.H.A.S.
Ayeni I.S.
author_sort Samadi M.
title Influence of elevated temperatures on the mechanical behavior of one-part coal ash geopolymer concrete with sodium metasilicate pentahydrate and sodium metasilicate anhydrous as alkaline activators
title_short Influence of elevated temperatures on the mechanical behavior of one-part coal ash geopolymer concrete with sodium metasilicate pentahydrate and sodium metasilicate anhydrous as alkaline activators
title_full Influence of elevated temperatures on the mechanical behavior of one-part coal ash geopolymer concrete with sodium metasilicate pentahydrate and sodium metasilicate anhydrous as alkaline activators
title_fullStr Influence of elevated temperatures on the mechanical behavior of one-part coal ash geopolymer concrete with sodium metasilicate pentahydrate and sodium metasilicate anhydrous as alkaline activators
title_full_unstemmed Influence of elevated temperatures on the mechanical behavior of one-part coal ash geopolymer concrete with sodium metasilicate pentahydrate and sodium metasilicate anhydrous as alkaline activators
title_sort influence of elevated temperatures on the mechanical behavior of one-part coal ash geopolymer concrete with sodium metasilicate pentahydrate and sodium metasilicate anhydrous as alkaline activators
publisher Elsevier Ltd
publishDate 2025
_version_ 1825816271718973440
score 13.244413

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