Enhanced far-field coherent thermal emission using mid-infrared bilayer metasurfaces

A classical thermal source, such as an incandescent filament, radiates according to Planck’s law. The feasibility of super-Planckian radiation has been investigated with sub-wavelength-sized sources in the last decade. In such sources, a crystal-dependent coupling of photons and optical phonons is possible at thermal energies corresponding to that of room temperature. This interaction can be used to tailor the far-field thermal emission in a coherent manner, however, understanding heat transfer during this processes is still nascent. Here, we used a novel measurement platform to quantify thermal signals in Ge₂Sb₂Te₅/SiO₂ nanoribbon structure. We were able to separate and quantify the radiated, and conducted heat transfer mechanisms. The thermal emission from the Ge₂Sb₂Te₅/SiO₂ nanoribbons was enhanced by 3.5× compared to that of a bare SiO₂ nanoribbon. Our model revealed that this enhancement was direct due to polaritonic heat transfer, which was possible due to the large and lossless dielectric permittivity of Ge₂Sb₂Te₅ at mid-IR frequencies. This study directly probes the far-field emission with a thermal gradient stimulated by Joule heating in temperature ranges from 100 to 400 K, which bridges the gap between mid-IR optics and thermal engineering.