Near-field radiative heat transfer between dissimilar materials mediated by coupled surface phonon- and plasmon-polaritons

TL;DR

This study measures and analyzes near-field radiative heat transfer between dissimilar materials supporting surface polaritons, demonstrating modulation capabilities and potential for energy and thermal management applications.

Contribution

It provides experimental measurements and theoretical validation of NFRHT between dissimilar materials with coupled surface polaritons, highlighting spectral mismatch effects and monochromatic enhancement.

Findings

Flux enhancement of ~8.2 beyond blackbody limit for SiC-Si

Resonant flux ~5 times larger for SiC-Si compared to Si-Si

Near-field enhancement is modulated by surface polariton coupling

Abstract

Near-field radiative heat transfer (NFRHT) between dissimilar materials supporting surface polaritons in the infrared is of critical importance for applications such as photonic thermal rectification and near-field thermophotovoltaics. Here, we measure NFRHT between millimetersize surfaces made of 6H-SiC and doped Si, respectively supporting surface phonon-polaritons (SPhPs) and surface plasmon-polaritons (SPPs) in the infrared, separated by a 150-nm-thick vacuum gap spacing maintained via SiO2 nanopillars. For purpose of comparison, measurements are also performed between two doped Si surfaces. The measured radiative flux is in good agreement with theoretical predictions based on fluctuational electrodynamics. A flux enhancement beyond the blackbody limit of ~ 8.2 is obtained for the SiC-Si sample, which is smaller than the enhancement for the Si-Si sample (~ 12.5) owing to the spectral mismatch of the SiC and Si light lines, and SPhP and SPP resonances. However, due to lower losses in SiC than Si and weaker SPhP-SPP coupling than SPP coupling, the near-field enhancement for the SiC-Si sample exhibits a more pronounced monochromatic behavior with a resonant flux that is ~ 5 times larger than the resonant flux for the Si-Si sample. This work demonstrates that it is possible to modulate NFRHT via surface polariton coupling, and will accelerate the development of energy conversion and thermal management devices capitalizing on the near-field effects of thermal radiation between dissimilar materials.