Engineering the spectral and spatial dispersion of thermal emission via polariton-phonon strong coupling

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Abstract

Strong coupling between optical modes can be implemented into nanophotonic design to modify the energy- momentum dispersion relation. This approach offers potential avenues for tuning the thermal emission frequency, line width, polarization, and spatial coherence. Here, we employ three-mode strong coupling between propagating and localized surface phonon polaritons, with zone-folded longitudinal optic phonons within periodic arrays of 4H-SiC nanopillars. Energy exchange, mode evolution, and coupling strength between the three polariton branches are explored experimentally and theoretically. The influence of strong coupling upon the angle-dependent thermal emission was directly measured, providing excellent agreement with theory. We demonstrate a 5-fold improvement in the spatial coherence and 3-fold enhancement of the quality factor of the polaritonic modes, with these hybrid modes also exhibiting a mixed character that could enable opportunities to realize electrically driven emission. Our results show that polariton-phonon strong coupling enables thermal emitters, which meet the requirements for a host of IR applications in a simple, lightweight, narrow-band, and yet bright emitter.

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Lu, G., Gubbin, C. R., Nolen, J. R., Folland, T., Tadjer, M. J., de Liberato, S., & Caldwell, J. D. (2021). Engineering the spectral and spatial dispersion of thermal emission via polariton-phonon strong coupling. Nano Letters, 21(4), 1831–1838. https://doi.org/10.1021/acs.nanolett.0c04767

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