Crystallization‐induced suppression of intumescence in aqueous alkali silicates

Thermal properties of aqueous alkali silicates have been investigated to establish a fundamental understanding of the structural state of silicate network and its impact on intumescence, up to 450°C. Foaming behavior is dependent upon the type of alkali ion (Na, K, Li) as well as composition as evid...

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Bibliographic Details
Published in:Journal of the American Ceramic Society 2023-01, Vol.106 (1), p.639-656
Main Authors: Mohsin, Hamza, Burov, Ekaterina, Tusseau‐Nenez, Sandrine, Maron, Sébastien, Devys, Lucie, Gacoin, Thierry, Gouillart, Emmanuelle
Format: Article
Language:English
Subjects:
Chemical Sciences
Crystallization
Foaming
heat treatments
intumescence/foaming
Lithium
Material chemistry
Metal ions
NMR
Nuclear magnetic resonance
Phase separation
Silicates
Sodium
Thermodynamic properties
Thermogravimetric analysis
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Summary:Thermal properties of aqueous alkali silicates have been investigated to establish a fundamental understanding of the structural state of silicate network and its impact on intumescence, up to 450°C. Foaming behavior is dependent upon the type of alkali ion (Na, K, Li) as well as composition as evidenced from a combination of tools involving thermogravimetric analysis, nuclear magnetic resonance, and X‐ray diffraction. Na silicates show extensive foaming, Li‐silicates do not foam, whereas K‐silicates exhibit an intermediate behavior depending upon the starting state and heating kinetics. Crystallization is observed for K‐ and Li‐silicates but not in the case of Na‐silicates and appears to be a limiting factor for macroscopic structural expansion. Quantitative analysis of different species reveals the network to be relatively mobile, in terms of its ability to reorganize, in pre‐dried (at 150°C) Na‐silicates. A reduction in this mobility is seen for K‐silicates as crystallization reduces K ions and silanols in the amorphous phase at and above 150°C, thus reducing the extent of foaming. In contrast, phase separation coupled with crystallization resulting in a complete exit of Li ions from the amorphous phase tends to suppress completely the intumescent phenomenon.
ISSN:0002-7820
1551-2916
DOI:10.1111/jace.18711