Dielectric permittivity tensor dynamics of in-plane hyperbolic van der Waals MoOCl2 and emergent chiral photonic applications

TL;DR

This paper investigates the anisotropic dielectric properties of vdW MoOCl2 across UV to NIR spectra, revealing hyperbolic and chiral photonic potential for advanced nanophotonic devices.

Contribution

It provides detailed dielectric tensor dynamics of vdW MoOCl2 and introduces a novel approach for designing chiral circular polarizers using twisted heterostructures.

Findings

Identification of a new hyperbolicity window in UV spectrum.

Demonstration of vdW MoOCl2's potential for chiral nanophotonics.

Proposal of nanoscale circular polarizers based on twisted heterostructures.

Abstract

Van der Waals (vdW) crystals offer unique opportunities for modern nanophotonic applications owing to their intrinsic anisotropic nature. While most of them exhibit uniaxial anisotropy arising from weak out-of-plane vdW interaction, some of their representative families also exhibit an in-plane biaxial anisotropy. Among the latter, outstand vdW oxochlorides with in-plane axes of a different physical character (metallic or dielectric). Here, we present an accurate dynamics of dielectric permittivity tensor components of vdW MoOCl2 in the ultraviolet (UV) to visible (Vis) spectral region partly covering near-infrared (NIR). Addressing its enormously anisotropic optical constants, we focus on another hyperbolicity window of vdW MoOCl2 emerging in the UV spectral region that may potentially unlock rich light-matter interaction effects. Furthermore, we propose an approach towards designing nanoscale handedness preserved Vis light circular polarizers based on twisted helical vdW MoOCl2 heterostructures. Our findings display that vdW MoOCl2 provides a highly promising platform not only for hyperbolic, but also for chiral nanophotonic applications.