Coherent heat-wave generation in SrTiO3 using stimulated light-scattering
Abstract
Wave propagation of heat in solids, which is often called `second sound', has attracted increasing attention to its various potential applications such as in thermal diodes and waveguides. It has been suggested that ferroelectrics are strong candidates for thermal-wave media1, and several reports on an incipient ferroelectric, strontium titanate (SrTiO3), have shown a novel wave-like excitation in light-scattering spectra2,3. Second sound has been proposed as the most plausible origin for this excitation based on rather indirect demonstrations3,4. However, the lack of a direct demonstration still leaves controversy5 on the existence of second sound in SrTiO3. Here, we present a direct demonstration of an optically generated coherent heat wave, i.e, coherent second sound, in bulk single crystals of SrTiO3. The generated wave-excitation has a linear dispersion relation with the predicted velocity of second sound in SrTiO3, and is overdamped at high temperatures or low frequencies, exhibiting apparently diffusive behaviour with the decay rates defined by the known values of the thermal diffusivity of SrTiO3. This work offers not only convincing evidence for the existence of second sound in SrTiO3, but also a first demonstration of coherent generation and wave-control of gigahertz temperature fields in a 3D bulk material. As high-quality SrTiO3 is widely available, and it is also known as a mother material of superconductors, the coherent excitation of temperature wave in this material offers a pathway for potential novel wave-based applications in heat management such as construction of thermal waveguides and directional devices or heat-control of superconductivity.
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