Optically Induced Nanoscale Domain Transformation in Low-Strain BaTiO₃ Thin Films

Above-bandgap ultrafast optical excitation provides the means to extend the current state of understanding of polarization domain phenomena and the relationship between electronic dynamics and mesoscale transformation. We report a time-resolved synchrotron x-ray diffraction study of a BaTiO₃ film grown on a NdScO₃ substrate in which an optically induced domain transformation is observed. The key experimental feature is an optically induced change in the intensities and reciprocal space positions of the diffuse scattering patterns arising from aa*/ca* and ca₁/ca₂ domain configurations. Following above-bandgap optical excitation, the diffuse scattering intensity of the aa*/ca* domains increases within 1 ns while that of the ca₁/ca₂ domains decreases. The change in intensities indicates a transformation from the ca₁/ca₂ to the aa*/ca* domain configuration. The transformation is accompanied by polarization rotation toward the out-of-plane direction, which has the same time dependence as the intensity variation. The degree of the polarization rotation varies depending on the optical fluence and is different for the two domain configurations. The results show that the mechanism of the domain transformation is associated with the polarization rotation induced by the optical excitation.