Zircônia CO-dopada por compensação de cargas nos sistemas (ZrO2)1-(x+y)(InO1,5)x(MOz)y com MOz = TaO2,5, NbO2,5, MoO3 ou WO3, como revestimento para barreira térmica
Resumo
InO1.5-stabilized zirconia (InSZ) is a potential hot corrosion resistant thermal
barrier coating (TBC). However, the thermal instability prevents real applications
of InSZ-based TBC. This thesis investigates the hypothesis of co-doping
using the charge compensation to improve the phase stability of InSZ. Four
co-doping systems were synthesized by coprecipitation and studied:
(ZrO2)1-(x+y)(InO1.5)x(MOz)y with MOz = TaO2.5, NbO2.5, MoO3, or WO3. After
synthesis, 9 mol% of InO1.5 plus the charge-compensating oxides was sufficient
to stabilize the tetragonal phase. Specific surface area up to 106.1 m2.g-1 and
crystallite size ~11 nm were achieved using ethanol washing followed by
azeotropic distillation as dehydration technique in the precipitates. In these
powders, initial thermal stability analysis indicated instability of the tetragonal
phase, with extension of the t→m transformation less detrimental in the InMoSZ
system. Further increase in the concentration of InO1.5:MoO3 results in
monophasic samples with retention of cubic phase in the InMoSZ. Cubic
InMoSZ exhibited hardness and thermal expansion coefficient of 13.5% and 9%
higher than those of InSZ, respectively. However, thermal treatments at
T ≥ 1200 °C showed that the InMoSZ is also passive to destabilization of the
high temperature cubic polymorph. Although the cubic InMoSZ was the most
promising system found in this thesis, the stability results do not support its
application as TBC for temperatures ≥ 1000 ºC. A deep evaluation of the phase
transformations between 1000 to 1200 °C indicated that the instability of the
proposed systems is due to a progressive c→t→m destabilization of the
polymorphs. This c→t→m transformation is directly associated with the
reduction of the InO1.5 stabilizer in solid solution by volatilization as In2O during
heat treatment. At temperatures ≤ 800 ºC, the c→t phase transformation do not
occurs, then, InSZ-based TBC is stable in these conditions.