A microwave/conventional hybrid furnace has been used to sinter
three ceramics with different microwave absorption characteristics
under pure conventional and a range of microwave/
conventional hybrid heating regimes. The precursor powder particle
size was also varied for each material. In each case it was
ensured that every sample within a series had an identical thermal
history in terms of its temperature/time profile. An increase
in both the onset of densification and the final density achieved
was observed with an increasing fraction of microwave energy
used during sintering, the effect being greatest for the materials
that absorbed microwaves most readily. Twenty-three percent
greater densification was observed for submicron zinc oxide
powder, the material with the largest microwave absorption capability,
when sintered using hybrid heating involving 1 kW of
microwave power compared with pure conventional power under
otherwise identical conditions. For the ceramic with the lowest
microwave absorption characteristic, alumina, the increase in
densification was extremely small; partially stabilized zirconia,
a moderate microwave absorber, was intermediate between the
two. Temperature gradients within the samples, a potential
cause of the effect, were assessed using two different approaches
and found to be too small to explain the results. Hence, it is
believed that clear evidence has been found to support the existence
of a genuine ‘‘microwave effect.’’
History
School
Aeronautical, Automotive, Chemical and Materials Engineering
Department
Materials
Pages
569988 bytes
Citation
WANG, BINNER and VAIDHYANATHAN, 2006. Evidence for the microwave effect during hybrid sintering. Journal of the American Ceramic Society, 89(6), pp. 1977-1984