Effect of Elevated Temperature on the Behavior of Amorphous Metallic Fibre-Reinforced Cement and Geopolymer Composites

To improve the tensile, flexural, and ductility properties of geopolymer composites, amorphous metallic fibres (AMF) are used to reinforce these composites, and the behavior of these composites at elevated temperatures has been assessed in this study. Four types of composites, i.e., cement, reinforced cement, geopolymer, and reinforced geopolymer composites have been prepared. The composites have been reinforced using AMF with a fibre volume fraction of 0.75%. The composites have been assessed for change in mass loss, cracking, compressive strength, and flexural strength at four elevated temperatures of 200 degrees C, 400 degrees C, 600 degrees C, and 800 degrees C, and conclusions have been drawn concerning these composites. The results have shown that an increase in temperature has an adverse effect on these composites, and geopolymer composites exhibit higher performance than their counterpart cement composites at elevated temperatures. The mass loss and surface cracking were significantly lower in geopolymer composites, and the fibre reinforcement had a negligible effect on mass loss. Also, the residual compressive and flexural strength of reinforced geopolymer composites was significantly higher than that of the reinforced cement composites. In addition, scanning electron microscopic images also showed that even at higher temperatures, the geopolymer matrix is present on the AMF fibre, which results in higher residual strength than the cement composites in which a negligible amount of matrix is present on the fibres.

Automated summary

This study evaluated the behavior of geopolymer composites reinforced with amorphous metallic fibres (AMF) at elevated temperatures to improve their tensile, flexural, and ductility properties. Four types of composites were prepared: cement, reinforced cement, geopolymer, and reinforced geopolymer composites. The composites were assessed for mass loss, cracking, compressive strength, and flexural strength at temperatures ranging from 200 to 800 degrees C. The results showed that geopolymer composites exhibited better performance than cement composites at elevated temperatures, with lower mass loss and surface cracking, and significantly higher residual compressive and flexural strength.