Optical pulse induced ultrafast antiferrodistortive transition in SrTiO3

TL;DR

This study demonstrates ultrafast optical pulse-induced phase transitions in SrTiO3, revealing rapid tetragonal-to-cubic and cubic-to-tetragonal transformations on picosecond timescales, with potential implications for information processing and energy storage.

Contribution

It provides the first direct observation of ultrafast, reversible phase transitions in SrTiO3 induced by optical pulses, linking structural dynamics to phonon behavior.

Findings

Thermally driven tetragonal-to-cubic transition detected via Brillouin scattering.

Optical pulses induce instantaneous cubic phase in tetragonal SrTiO3.

Reverse cubic-to-tetragonal transition occurs within hundreds of picoseconds.

Abstract

The ultrafast dynamics of the antiferrodistortive (AFD) phase transition in perovskite SrTiO3 is monitored via time-domain Brillouin scattering. Using femtosecond optical pulses, we induce a thermally driven tetragonal-to-cubic structural transformation and detect notable changes in the frequency of Brillouin oscillations (BO) induced by propagating acoustic phonons. First, we establish a fingerprint frequency of different regions across the temperature phase diagram of the AFD transition characterized by tetragonal and cubic phases in the low and high temperature sides, respectively. Then, we demonstrate that in a sample nominally kept in tetragonal phase, deposition of sufficient thermal energy induces an instantaneous transformation of the heat-affected region to the cubic phase. Coupling the measured depth-resolved BO frequency with a time and depth-resolved heat diffusion model, we detect a reverse cubic-to-tetragonal phase transformation occurring on a time scale of hundreds of picoseconds. We attribute this ultrafast phase transformation in the perovskite to a structural resemblance between atomic displacements of the R-point soft optic mode of the cubic phase and the tetragonal phase, both characterized by anti-phase rotation of oxygen octahedra. Evidence of such a fast structural transition in perovskites can open up new avenues in the field of information processing and energy storage.