Quenched lattice fluctuations in optically driven SrTiO3

TL;DR

This study investigates how intense mid-infrared pulses affect lattice fluctuations in SrTiO3, revealing a long-lived suppression of antiferrodistortive fluctuations that could influence light-induced ferroelectricity.

Contribution

It demonstrates the first direct measurement of quenched lattice fluctuations in SrTiO3 under optical driving, linking nonlinear phononic interactions to non-equilibrium structural dynamics.

Findings

Long-lived quench of antiferrodistortive lattice fluctuations observed

Lattice fluctuation changes explained by nonlinear phononic interactions

Provides new insights into light-induced ferroelectricity mechanisms

Abstract

Many functionally relevant ferroic phenomena in quantum materials can be manipulated by driving the lattice coherently with optical and terahertz pulses. New physical phenomena and non-equilibrium phases that have no equilibrium counterpart have been discovered following these protocols. The underlying structural dynamics has been mostly studied by recording the average atomic position along dynamical structural coordinates with elastic scattering methods. However, crystal lattice fluctuations, which are known to influence phase transitions in equilibrium, are also expected to determine these dynamics but have rarely been explored. Here, we study the driven dynamics of the quantum paraelectric SrTiO3, in which mid-infrared drives have been shown to induce a metastable ferroelectric state. Crucial in these physics is the competition between the polar instability and antiferrodistortive rotations, which in equilibrium frustrate the formation of long-range ferroelectricity. We make use of high intensity mid-infrared optical pulses to resonantly drive a Ti-O stretching mode at 17 THz, and we measure the resulting change in lattice fluctuations using time-resolved x-ray diffuse scattering at a free electron laser. After a prompt increase, we observe a long-lived quench in R-point antiferrodistortive lattice fluctuations. The enhancement and reduction in lattice fluctuations are explained theoretically by considering fourth-order nonlinear phononic interactions and third-order coupling to the driven optical phonon and to lattice strain, respectively. These observations provide a number of new and testable hypotheses for the physics of light-induced ferroelectricity.