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Optimized Colossal Near‐Field Thermal Radiation Enabled by Manipulating Coupled Plasmon Polariton Geometry

Kezhang Shi, Zhaoyang Chen, Xinan Xu, Julian Evans, Sailing He

2021Advanced Materials72 citationsDOIOpen Access PDF

Abstract

Collective optoelectronic phenomena such as plasmons and phonon polaritons can drive processes in many branches of nanoscale science. Classical physics predicts that a perfect thermal emitter operates at the black body limit. Numerous experiments have shown that surface phonon polaritons allow emission two orders of magnitude above the limit at a gap distance of ≈50 nm. This work shows that a supported multilayer graphene structure improves the state of the art by around one order of magnitude with a ≈1129-fold-enhancement at a gap distance of ≈55 nm. Coupled surface plasmon polaritons at mid- and far-infrared frequencies allow for near-unity photon tunneling across a broad swath of k-space enabling the improved result. Electric tuning of the Fermi-level allows for the detailed characterization and optimization of the colossal nanoscale heat transfer.

Topics & Concepts

Materials sciencePlasmonPolaritonThermalThermal radiationMetamaterialField (mathematics)Near and far fieldRadiationOptoelectronicsOpticsNanotechnologyGeometryPhysicsMathematicsMeteorologyThermodynamicsPure mathematicsThermal Radiation and Cooling TechnologiesQuantum Electrodynamics and Casimir EffectUrban Heat Island Mitigation
Optimized Colossal Near‐Field Thermal Radiation Enabled by Manipulating Coupled Plasmon Polariton Geometry | Litcius