Abstrakt
Microcracking in illite-based ceramic bodies and its influence on their bulk properties were investigated by means of the acoustic emission (AE) technique during the cooling stage of firing up to different maximum temperatures (800-1200 degrees C). Because of the mismatch of the thermal expansion coefficients between the glassy phase and the quartz particles, radial microcracking around quartz grains began to occur at similar to 750 degrees C (temperature of glass transition).
At similar to 573 degrees C, where ther beta -> alpha transformation of quartz takes place, a non-monotonic behavior of the Young's modulus and a temporary cessation of the AE activity occurred. Below this temperature, the AE signals appeared again, reflecting the formation of circumferential cracks around the particles.
The presence of circumferential microcracks was also confirmed by the use of scanning electron microscopy.