Lithography-free directional control of thermal emission

TL;DR

This paper demonstrates a lithography-free method to control the directionality of thermal emission using a Salisbury screen with hexagonal Boron Nitride, enabling highly directional thermal radiation.

Contribution

It introduces an analytical approach to achieve directional thermal emission through dielectric permittivity interplay, using a simple planar Salisbury screen with hBN.

Findings

Analytical model links dielectric properties to emission directionality.

Hexagonal Boron Nitride can produce grating-like emission lobes.

Method avoids complex nanostructuring and lithography.

Abstract

Blackbody thermal emission is spatially diffuse. Achieving highly directional thermal emission typically requires nanostructuring the surface of the thermally emissive medium. The most common configuration is a subwavelength grating that scatters surface polaritonic modes from the near-field to the far-field and produces antenna-like lobes of thermal emission. This concept, however, is typically limited to a particular linear polarization, and requires sophisticated lithography. Here, we revisit the simple motif of a planar Salisbury screen. We show analytically how the interplay between the real and imaginary part of the dielectric permittivity of the emitter layer defines the directional characteristics of emission, which can range from diffuse to highly directional. We propose a realistic configuration and show that hexagonal Boron Nitride thin films can enable grating-like thermal emission lobes in a lithography-free platform.