Effects of SnO₂ and Glass Particle Size on the Microstructure and the Electrical Properties of SnO₂-Glass Composites

Abstract

The effects of the particle size of SnO₂ and glass on the densification behavior, the microstructure and the electrical properties of SnO₂-glass composites were examined. Moreover, the relationship between the electrical properties of the glass composites and the particle dispersion of SnO₂ in a glass matrix was discussed following quantitative analysis of SnO₂ particle dispersion by computer-assisted image analysis on SEM photographs. The results are summarized as follows: (1) when coarse grained SnO₂ particles were used, the densification of the glass composites proceeded at low firing temperatures. Therefore, the use of coarse SnO₂ particles was useful to get the glass composite having a high electrical conductivity and a small negative temperature coefficient of resistance (TCR) at low firing temperatures. However, after the completion of densification, the glass composite prepared using fine SnO₂ particles showed a higher electrical conductivity and a smaller negative TCR because SnO₂ particles were more highly crowded in a glass matrix and thus the SnO₂ interparticle spacings were smaller than those of the sample dispersed with coarse SnO₂ particles. (2) when fine glass particles were used, the densification of the glass composites proceeded at low firing temperatures and the particle dispersion of SnO₂ in a glass matrix was homogeneous. Besides, the glass composite prepared using fine glass particles showed a high electrical conductivity and a small negative TCR at low firing temperatures. On the other hand, at high firing temperature, the glass composite having a higher conductivity and a smaller negative TCR was obtained when coarse glass particles were used, because the densely aggregated SnO₂ particles formed highly conductive networks in a glass matrix.