Abstract
The synthesis of nanopowders of terbia compounds with scandia, yttria, and lutetia was carried out using a self-propagating high-temperature synthesis method involving a mixture of nitrates of metals and glycine as a precursor. The nanopowder phase transformations were investigated using X-ray diffraction analysis. It was found that lutetia has a negligible effect on the phase formation in terbia. On the other hand, yttrium and scandium ions significantly suppressed crystallization. The densification kinetics of nanopowders of the Tb2O3 compounds and the microstructure of ceramics after microwave sintering were studied using dilatometry and scanning electron microscopy. The introduction of scandia, yttria, or lutetia contributed to the intensification of the densification of the terbia ceramics when heated in a microwave field. Near full-density materials of terbia solid solutions with lutetia and yttria were obtained at about 1600–1640 °C. The ceramics of scandia–terbia compounds contained the second phase, which causes light scattering.
Highlights
The fabrication of new crystalline materials for extreme light fields is one of the priorities of the science of advanced laser materials
Nanopowders of terbia compounds with scandia, yttria, and lutetia were successfully produced by the SHS method using a mixture of nitrates of metals and glycine as a precursor
The X-ray diffraction (XRD) patterns have indicated that the (Y1–xTbx)2O3 and (Lu1–xTbx)2O3 samples (x = 0.3, 0.6, 0.9) represent solid solutions of yttria or lutetia and terbia
Summary
The fabrication of new crystalline materials for extreme light fields is one of the priorities of the science of advanced laser materials. One of the most important tasks of the Tb2O3 ceramics technology is the search for sintering aid, in that this can promote sintering at lower temperatures, and/or can prevent the phase transitions at sintering temperatures and/or suppress mechanical stress caused by these phase transitions. Such aids (or components, due to their high concentration in ceramics) may be rare earth sesquioxides (REO) such as Y2O3, Sc2O3, or Lu2O3. We study of the effect of scandia, yttria, and lutetia concentrations on the phase composition and the densification kinetics of the obtained powders, as well as the possibility of producing ceramics from these powders
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