Long-distance near-field energy transport via propagating surface waves

TL;DR

This paper demonstrates that surface phonon polaritons can enable long-distance near-field energy transfer between nanoparticles and substrates, surpassing traditional limits and opening new avenues for energy transport.

Contribution

It introduces a novel mechanism for long-distance near-field energy transfer via propagating surface waves coupling with localized surface phonon polaritons.

Findings

Energy transfer exceeds far-field limit at large distances.

Coupling between localized and propagating SPhPs enhances RHT.

Chain of nanoparticles also shows significant energy transfer.

Abstract

Near-field radiative heat transfer (RHT) between two bodies can significantly exceed the far-field limit set by Planck's law due to the evanescent wave tunneling, which typically can only occur when the two bodies are separated at subwavelength distances. We show that the RHT between two SiC nanoparticles with separation distances much larger than the thermal wavelength can still exceed the far-field limit when the particles are located within a subwavelength distance away from a SiC substrate. In this configuration, the localized surface phonon polariton (SPhP) of the particles couples to the propagating SPhP of the substrate which then provides a new channel for the near-field energy transport and enhances the RHT by orders of magnitude at large distances. The enhancement is also demonstrated to appear in a chain of closely spaced SiC nanoparticles located in the near field of a SiC substrate. The findings provide a new way for the long-distance transport of near-field energy.