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Directional Radiative Cooling via Exceptional Epsilon-Based Microcavities

Jin-Woo Cho, Yun-Jo Lee, Jae‐Hyun Kim, Run Hu, Eungkyu Lee, Sun‐Kyung Kim

2023ACS Nano76 citationsDOI

Abstract

The advent of nanophotonics enables the regulation of thermal emission in the momentum domain as well as in the frequency domain. However, earlier attempts to steer thermal emission in a certain direction were restricted to a narrow spectrum or specific polarization, and thus their average (8–14 μm) emissivity (ε av ) and angular selectivity were nominal. Therefore, the practical uses of directional thermal emitters have remained unclarified. Here, we report broadband, polarization-irrelevant, amplified directional thermal emission from hollow microcavities covered with deep-subwavelength-thickness oxide shells. A hexagonal array of SiO 2 /AlO X (100/100 nm) hollow microcavities designed by Bayesian optimization exhibited ε av values of 0.51–0.62 at 60°–75° and 0.29–0.32 at 5°–20°, yielding a parabolic antenna-shaped distribution. The angular selectivity peaked at 8, 9.1, 10.9, and 12 μm, which were identified as the epsilon-near-zero (via Berreman modes) and maximum-negative-permittivity (via photon-tunneling modes) wavelengths of SiO 2 and AlO X, respectively, thus supporting phonon–polariton resonance mediated broadband side emission. As proof-of-concept experiments, we demonstrated that these exceptional epsilon-based microcavities could provide thermal comfort to users and practical cooling performance to optoelectronic devices.

Topics & Concepts

EmissivityNanophotonicsPhononOptoelectronicsMaterials sciencePolarization (electrochemistry)ThermalThermal radiationOpticsAngular momentumPhysicsCondensed matter physicsChemistryQuantum mechanicsPhysical chemistryMeteorologyThermodynamicsThermal Radiation and Cooling TechnologiesQuantum Electrodynamics and Casimir EffectOptical properties and cooling technologies in crystalline materials
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