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Single crystals of sodium bismuth titanate (Na0.5Bi0.5TiO3, NBT) (pure and Mn-doped) have been investigated by means of optical birefringence microscopy. For both crystals, it was found that, above ∼573 K, the optical axis is perfectly aligned with one of the pseudocubic 〈001〉PC directions, while the domain walls appearing in the images are parallel to the pseudocubic 〈011〉PC directions. These observations are consistent with a tetragonal symmetry. Below ∼573 K, the observed optical orientation of both crystals shows a broad angular distribution, with no clearly visible crystallographically oriented domain walls. These results are consistent with monoclinic symmetry. Most importantly, the direct observation of the temperature-driven rotation of the optical axis within the monoclinic plane is reported for the first time in a perovskite oxide material, in the present case for Mn-doped NBT. This has consequences for the understanding of phase transitions in technologically relevant compounds, such as PbZr1−xTixO3, which are considered to have monoclinic structure in some parts of the phase diagram.

Supporting information

wmv

Windows Media Video (WMV) file https://doi.org/10.1107/S0021889812008217/ks5305sup1.wmv
Temperature dependence of optical birefringence and distribution of orientation angles in the pure NBT crystal. See Figs. 2–3 for more details. High-resolution version.

wmv

Windows Media Video (WMV) file https://doi.org/10.1107/S0021889812008217/ks5305sup2.wmv
Temperature dependence of optical birefringence and distribution of orientation angles in the Mn-doped NBT crystal. See Figs. 5–6 for more details. High-resolution version.

wmv

Windows Media Video (WMV) file https://doi.org/10.1107/S0021889812008217/ks5305sup3.wmv
Temperature dependence of optical birefringence in the pure NBT crystal. See Fig. 2 for more details. High-resolution version.

wmv

Windows Media Video (WMV) file https://doi.org/10.1107/S0021889812008217/ks5305sup4.wmv
Temperature dependence of optical birefringence in the Mn-doped NBT crystal. See Fig. 5 for more details. High-resolution version.

avi

AVI file https://doi.org/10.1107/S0021889812008217/ks5305sup5.avi
Temperature dependence of optical birefringence and distribution of orientation angles in the pure NBT crystal. See Figs. 2–3 for more details. Low-resolution version.

avi

AVI file https://doi.org/10.1107/S0021889812008217/ks5305sup6.avi
Temperature dependence of optical birefringence and distribution of orientation angles in the Mn-doped NBT crystal. See Figs. 5–6 for more details. Low-resolution version.

avi

AVI file https://doi.org/10.1107/S0021889812008217/ks5305sup7.avi
Temperature dependence of optical birefringence in the pure NBT crystal. See Fig. 2 for more details. Low-resolution version.

avi

AVI file https://doi.org/10.1107/S0021889812008217/ks5305sup8.avi
Temperature dependence of optical birefringence in the Mn-doped NBT crystal. See Fig. 5 for more details. Low-resolution version.


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