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Violating Kirchhoff’s Law of Thermal Radiation in Semitransparent Structures

Yubin Park, Viktar S. Asadchy, Bo Zhao, Cheng Guo, Jiahui Wang, Shanhui Fan

2021ACS Photonics88 citationsDOIOpen Access PDF

Abstract

Kirchhoff’s law of thermal radiation imposes a constraint on photon-based energy harvesting processes since part of the incident energy flux is inevitably emitted back to the source. By breaking the reciprocity of the system, it is possible to overcome this restriction and improve the efficiency of energy harvesting. Here, we design and analyze a semitransparent emitter that fully absorbs normally incident energy from a given direction with zero backward and unity forward emissivity. The nearly ideal performance with wavelength-scale thickness is achieved due to the magneto-optical effect and the guided-mode resonance engineered in the emitter structure. We derive the general requirements for the nonreciprocal emitter using the temporal coupled mode theory and the symmetry considerations. Finally, we provide a realistic emitter design based on a photonic crystal slab consisting of a magnetic Weyl semimetal and silicon.

Topics & Concepts

Common emitterThermal radiationReciprocity (cultural anthropology)ThermalRadiationSlabPhotonic crystalRadiant energyOpticsPhysicsResonance (particle physics)Ideal (ethics)Energy (signal processing)PhotonicsEnergy transformationElectromagnetic radiationSymmetry (geometry)Symmetry breakingThermal energyOptoelectronicsEnergy fluxCrystal (programming language)OpacityMagnetic fluxMagnetic fieldFlux (metallurgy)Radiative transferMaterials scienceSnell's lawConstraint (computer-aided design)Computational physicsLawHeat fluxThermal Radiation and Cooling TechnologiesPhotonic Crystals and ApplicationsMetamaterials and Metasurfaces Applications
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