Fundamentals of polaritons in strongly anisotropic thin crystal layers

TL;DR

This paper provides a comprehensive theoretical analysis of anisotropic polaritons in thin biaxial layers, introducing a novel methodology for their representation and revealing key insights into their propagation, classification, and unique modes, with broad applicability.

Contribution

It introduces a new analytical approach to represent isofrequency curves considering non-parallel real and imaginary wavevector parts, and classifies polaritonic modes in biaxial layers.

Findings

Imaginary part of wavevector aligns with group velocity.

Distinct dispersion and loss characteristics for volume and surface modes.

Discovery of anisotropic transverse electric modes with natural canalization.

Abstract

Polaritons in strongly anisotropic thin layers have recently captured the attention in nanophotonics because of their directional propagation at the nanoscale, which offers unique possibilities for nanooptical applications. However, exploiting the full potential of anisotropic polaritons requires a thorough understanding of their properties, including field confinement, energy and phase propagation direction and losses. Here we fill this critical gap by providing fundamental insights into the propagation of anisotropic polaritons in thin biaxial layers. In particular, we introduce a novel methodology that allows us to represent isofrequency curves of polaritons in strongly anisotropic materials considering that the real and imaginary parts of the wavevector are not parallel. In fact, we analytically show that the direction of the imaginary part of the wavevector is parallel to the group velocity, which can have different, even perpendicular or opposite, directions with respect to the phase velocity. This finding is crucial for understanding polaritonic phenomena in anisotropic media, yet it has so far been widely overlooked in the literature. Additionally, we introduce a criterion for classifying the polaritonic modes in biaxial layers into volume and surface categories, and analyze their dispersion, field structure, and losses. Finally, we discover the existence of anisotropic transverse electric modes, which can exhibit natural canalization. Taken together, our results shed light on hitherto unexplored areas of the theory of electromagnetic modes in thin biaxial layers. Although exemplified for van der Waals MoO3 layers, our findings are general for polaritons in other strongly anisotropic biaxial hyperbolic crystals.