Polarimetric analysis of thermal emission from both reciprocal and nonreciprocal materials using fluctuational electrodynamics

TL;DR

This paper develops a polarimetric analysis framework for thermal emission from reciprocal and nonreciprocal materials, enabling detailed characterization of polarization states using fluctuational electrodynamics, with implications for designing thermal emitters.

Contribution

It introduces a comprehensive method to analyze thermal emission polarization in nonreciprocal media without relying on Kirchhoff's law, extending the understanding of emissivity in complex materials.

Findings

Thermal emission can be circularly or linearly polarized depending on frequency and direction.

The analysis confirms the validity of modified Kirchhoff's law for nonreciprocal materials.

The method enables precise control of thermal emission polarization for energy applications.

Abstract

Coherent thermal emission for a given polarization has been observed in many metamaterials with micro/nanostructures. A complete description of the thermal emission requires the full characterization of the spectral angular emissivity for all polarization states. Emissivity is typically obtained based on the equivalence between the absorptivity and emissivity according to Kirchhoff's law; however, such relation may be invalid for nonreciprocal media. More general approaches without the constrain of optical reciprocity are necessary when dealing with magneto-optical materials and magnetic Weyl semimetals. Here, a polarimetric analysis of thermal emission is carried out based on fluctuational electrodynamics. The Stokes parameters are obtained using coherency matrix for a multilayered system with anisotropic media, including nonreciprocal materials. The results demonstrate that thermal emission may be circularly or linearly polarized in different directions and frequencies. The findings are consistent with the statements of the modified Kirchhoff's law provided by several groups in recent years, and therefore, justify the appropriateness of both the direct and indirect methods. This study will help the design of desired thermal emitters for energy harvesting and thermal control.