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The effect of limestone on sodium hydroxide-activated metakaolin-based geopolymers
Highlights Matrix consisted of calcium silicate, alkali aluminosilicate, calcium carboaluminates. The heat treatment increased reaction of limestone only at higher 5mol NaOH. The leaching from limestone–metakaolin is controlled by equilibrium considerations.
Abstract Blends of metakaolin and limestone can be alkali-activated with NaOH to form solid binders, which show relatively low strength but offer potential as a model system by which the reaction processes of more complex systems can be better understood. The effects of curing procedure, limestone content and alkalinity of the activator are able to be related to the mineralogy, mechanical properties and microstructure of hardened pastes. The presence of limestone enhances the release of Al and Si ions from metakaolin, with the Al released in the early stages of the reaction being bound into AFm-type phases. Dissolution of LS is slightly higher when a lower alkalinity sodium hydroxide activator is used. The heat treatment of pastes activated with 3M NaOH solution resulted in a lower extent of reaction of limestone, while with 5M solution, heat-curing at early age resulted in more reaction. The main alkali-activation product in metakaolin–limestone–NaOH pastes is a geopolymer gel with inclusions of unreacted metakaolin, limestone particles, zeolite A, and AFm phases, with different zeolites such as faujasite-like and hydrosodalite phases also identified at higher reaction temperatures.
The effect of limestone on sodium hydroxide-activated metakaolin-based geopolymers
Highlights Matrix consisted of calcium silicate, alkali aluminosilicate, calcium carboaluminates. The heat treatment increased reaction of limestone only at higher 5mol NaOH. The leaching from limestone–metakaolin is controlled by equilibrium considerations.
Abstract Blends of metakaolin and limestone can be alkali-activated with NaOH to form solid binders, which show relatively low strength but offer potential as a model system by which the reaction processes of more complex systems can be better understood. The effects of curing procedure, limestone content and alkalinity of the activator are able to be related to the mineralogy, mechanical properties and microstructure of hardened pastes. The presence of limestone enhances the release of Al and Si ions from metakaolin, with the Al released in the early stages of the reaction being bound into AFm-type phases. Dissolution of LS is slightly higher when a lower alkalinity sodium hydroxide activator is used. The heat treatment of pastes activated with 3M NaOH solution resulted in a lower extent of reaction of limestone, while with 5M solution, heat-curing at early age resulted in more reaction. The main alkali-activation product in metakaolin–limestone–NaOH pastes is a geopolymer gel with inclusions of unreacted metakaolin, limestone particles, zeolite A, and AFm phases, with different zeolites such as faujasite-like and hydrosodalite phases also identified at higher reaction temperatures.
The effect of limestone on sodium hydroxide-activated metakaolin-based geopolymers
Cwirzen, Andrzej (Autor:in) / Provis, John L. (Autor:in) / Penttala, Vesa (Autor:in) / Habermehl-Cwirzen, Karin (Autor:in)
Construction and Building Materials ; 66 ; 53-62
13.05.2014
10 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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