Nucleation and crystallization of Ba2Si3O8 spherulites in a barium aluminum silicate glass, and mechanical properties of the obtained glass-ceramics

The effect of spherulitic crystallization on the elastic moduli and fracture toughness of a barium aluminum silicate glass was investigated. The crystallization process results in Ba2Si3O8 phase and is initiated from Ba rich nuclei. Nucleation is optimal in the 690-720 degrees C interval. Young's modulus is increased by 12.5% when the glass-ceramic conversion is nearly complete. Nevertheless, as the size and the volume fraction of crystals are increased, some microcracking shows up upon cooling from the crystallization temperature. An optimal improvement of the fracture toughness (SEPB method) by 27 % is observed for a 49 % volume fraction of 5 to 10 mu m large spherulites.

Automated summary

The study found that the elastic moduli and fracture toughness of barium aluminum silicate glass are significantly affected by spherulitic crystallization. As the size and volume fraction of crystals increase, microcracking appears in the glass upon cooling from the crystallization temperature. An optimal improvement in fracture toughness is observed when spherulites of 5 to 10 μm size constitute 49% of the volume.