Both theoretical analysis and transmission electron microscopy (TEM) c
omplementary studies have been conducted to evaluate the possible role
of subgrain formation as a strengthening mechanism in a nanocomposite
consisting of Al2O3 and 5 vol % 0.15 mu m SiC particles. The theoreti
cal calculation predicted that the residual stresses due to thermal ex
pansion mismatch between Al2O3 and SiC are insufficient to induce the
extensive plastic deformation required for subgrain formation upon ann
ealing. This prediction was consistent with TEM observations that the
bulk of the material was completely free from subgrains, and that only
a low density of dislocations was present in isolated areas. The resu
lts suggest, therefore, that microstructure refinement through subgrai
n formation can not account for the superior mechanical behaviour of t
he nanocomposite reported in previous studies. TEM examination of the
ground surfaces revealed significant plastic deformation in both singl
e phase Al2O3 and the nanocomposite. Upon annealing at 1300 degrees C
for 2 h, dislocation-free subgrains were formed in Al2O3, whereas a hi
gh density of tangled dislocations were present in the nanocomposite.
These observed differences are consistent with the fact that during an
nealing, residual stress relaxation is more difficult in the nanocompo
site than in Al2O3.