Properties and characterization of alumina platelet reinforced geopolymer composites

Geopolymers are porous, amorphous, alkali‐aluminosilicate hydrate materials formed at room temperature via a solution process. Geopolymer based on metakaolin had a relatively homogeneous microstructure that offered consistent behavior but suffered from dehydration cracking and large densification sh...

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Bibliographic Details
Published in:Journal of the American Ceramic Society 2020-09, Vol.103 (9), p.5178-5185
Main Authors: Kutyla, Gregory P., Kriven, Waltraud M.
Format: Article
Language:English
Subjects:
alumina
Aluminosilicates
Aluminum silicates
Amorphous materials
Castable refractories
Dehydration
Densification
Diameters
Dilatometry
Flexural strength
fracture mechanics/toughness
Geopolymers
Heat treatment
Metakaolin
microstructure
Platelets
processing
Properties (attributes)
Room temperature
Shock heating
Thermal shock
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Summary:Geopolymers are porous, amorphous, alkali‐aluminosilicate hydrate materials formed at room temperature via a solution process. Geopolymer based on metakaolin had a relatively homogeneous microstructure that offered consistent behavior but suffered from dehydration cracking and large densification shrinkages when heated. It was found that by reinforcing a metakaolin geopolymer of composition (K2O·Al2O3·4SiO2·11H2O) with 50 µm diameter alumina platelets, dehydration cracking could be prevented, and shrinkage could be reduced by an order of magnitude. Samples were reinforced with 30, 50, and 70 wt% of alumina platelets. Although the properties of the 30 and 50 wt% conditions were better than those of unreinforced geopolymer, those samples still showed warping, cracking, and strength losses on heating. The 70 wt% samples did not warp or crack when heated to temperatures of up to 1500°C. The room‐temperature 4‐point flexural strength of these samples remained at around 20 MPa regardless of heat treatments. The in situ measured flexural strength increased to almost 40 MPa at 600°C, and remained higher than 20 MPa until 1200°C. Samples subjected to propane‐torch thermal shock heating and subsequent quenching did not crack or fragment. Dilatometry, X‐ray diffraction, and scanning electron microscopy were used for additional characterization. Given these properties, this material showed promise as a castable refractory.
ISSN:0002-7820
1551-2916
DOI:10.1111/jace.17169