Thermal behavior of coal fly ash geopolymers: structural analysis supported by molecular dynamics and machine learning methods

Thermal behavior of coal fly ash geopolymers: structural analysis supported by molecular dynamics and machine learning methods

This contribution presents the results of structural investigations on the cured and high temperatures of three series of geopolymers. The specimens were synthesized at 80 °C from coal fly ash and three activators of variable composition based on sodium hydroxide and sodium silicate solutions. Struc...

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Bibliographic Details
Published in:Journal of thermal analysis and calorimetry Vol. 149; no. 10; pp. 4397 - 4409
Main Authors: Król, M., Stoch, P., Szymczak, P., Mozgawa, W.
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 2024
Springer Nature B.V
Subjects:
Algorithms
Aluminosilicates
Aluminum silicates
Analytical Chemistry
Chemical composition
Chemistry
Chemistry and Materials Science
Cluster analysis
Compressive strength
Crystallization
Disintegration
Dynamic structural analysis
Fly ash
Geopolymers
Heat treatment
High temperature
In situ measurement
Infrared spectroscopy
Inorganic Chemistry
Machine learning
Measurement Science and Instrumentation
Microstructural analysis
Molecular dynamics
Nepheline
Physical Chemistry
Polymer Sciences
Sodalite
Sodium hydroxide
Sodium silicates
Thermodynamic properties
Thermal properties
Amorphous gel
Alkali-activation
Principal component analysis (PCA)
Machine learning
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Summary:This contribution presents the results of structural investigations on the cured and high temperatures of three series of geopolymers. The specimens were synthesized at 80 °C from coal fly ash and three activators of variable composition based on sodium hydroxide and sodium silicate solutions. Structural and microstructural analysis was performed, especially using in-situ measurements of XRD patterns and IR spectra as a function of temperature. The cured compounds' phase content and compressive strength changed slightly depending on the starting chemical composition. All analyzed materials experience a mass loss due to water removal at 300 °C, followed by increased porosity from disintegrating compounds above 300 °C. Higher alkali content improves strength (400–600 °C) possibly due to nepheline formation. The amorphous phase gradually softens during heating, influenced by alkali content. Structural analyses were supported by model calculations of a number of aluminosilicate structures. The cluster analysis using the k-means algorithm was used to divide the PCA space into regions that represent structural similarities, and analyzing specific point positions in the space allowed for several conclusions to be drawn about the studied materials, including that changes in chemical composition and thermal treatment can promote the transformation from sodalite to nepheline and that the glass network has elements that are nepheline-like and may promote its crystallization.
ISSN:1388-6150
1588-2926
DOI:10.1007/s10973-024-13004-y