Abstract:
The low-temperature vibrational properties of Ba2ZnTeO6 double-perovskite ceramics obtained by the
solid-state route were investigated by Raman scattering and Fourier-transform infrared reflectivity. We found
that this material undergoes a reversible ferroelastic phase transition at around 140 K, well compatible with a
recently proposed rhombohedral-to-monoclinic structural change that would occur below 165 K. Complementary calorimetric measurements showed that the phase transition has a first-order character, with an entropy jump compatible with a displacive mechanism. The vibrational spectra show clearly the splitting of the doubly degenerate E modes into nondegenerate representations of the low-symmetry phase. In particular, the lowestfrequency Raman mode presents soft-mode behavior and splits below the critical temperature, confirming the in-plane ferroelastic deformation in the low-temperature phase.
