Transient translation symmetry breaking via quartic-order negative light-phonon coupling at the Brillouin zone boundary in KTaO3

Abstract

KTaO3 presents a rich hyper-Raman spectrum originating from two-phonon processes at the Brillouin zone boundary, indicating the possibility of driving these phonon modes using intense midinfrared laser sources. We obtained the coupling of light to the highest-frequency longitudinal optic phonon mode QHY at the X (0,0, 12) point by first principles calculations of the total energy as a function of the phonon coordinate QHY and electric field E. We find that the energy curve as a function of QHY softens for finite values of electric field, indicating the presence of QHY2 E2 nonlinearity with negative coupling coefficient. We studied the feasibility of utilizing this nonlinearity to transiently break the translation symmetry of the material by making the QHY mode unstable with an intense midinfrared pump pulse. We also considered the possibility that nonlinear phonon-phonon couplings can excite the lowest-frequency phonon coordinates QLZ and QLX at X when the QHY mode is externally driven. The nonlinear phonon-phonon couplings were also obtained from first principles via total-energy calculations as a function of the phonon coordinates, and these were used to construct the coupled classical equations of motion for the phonon coordinates in the presence of an external pump term on QHY. We numerically solved them for a range of pump frequencies and amplitudes and found three regimes where the translation symmetry is broken: i) rectification of the lowest-frequency coordinates due to large amplitude oscillation of the QHY coordinate about its equilibrium position, ii) rectification of only the QHY coordinate without displaced oscillations of the lowest-frequency coordinates, and iii) rectification of all three coordinates.