Mechanical and microstructural evolutions of fly ash/slag-based geopolymer at high temperatures: Effect of curing conditions

Designing a building material with excellent heat resistance is crucial for protection against catastrophic fires. Geopolymer materials have been investigated as they offer better heat resistance than traditional cement owing to their ceramic-like properties. Curing temperature and conditions are crucial factors that determine the properties of geopolymers, but their impacts on the heat resistance of geopolymers remain unclear. This study produced geopolymers from fly ash and ground granulated blast furnace slag by using sodium silicate and sodium hydroxide solutions as alkaline solutions. To examine the effect of curing conditions on the hightemperature performance of geopolymer, four different curing conditions, namely, heat curing (70 degrees C for 24 h), ambient curing (20 degrees C), water curing, and the combination of heat and water curing (70 degrees C for 24 h followed by water curing), were applied. At 28 d, the specimens were subjected to high temperatures (500 degrees C, 750 degrees C, and 950 degrees C), and their mechanical and microstructural evolutions were studied. The results revealed that the curing condition significantly affects the properties of the unexposed geopolymer; the effect on its high-temperature performance is insignificant. Furthermore, all the specimens could maintain adequate compressive strength after exposure to the maximum temperature of 950 degrees C, promising the use of geopolymer for structural applications.

Automated summary

Designing a building material with excellent heat resistance is important for protecting against catastrophic fires. Geopolymer, a material with ceramic-like properties, has better heat resistance than traditional cement and has been investigated as a potential solution. However, the impact of curing temperature and conditions on the heat resistance of geopolymers is still unclear.