Topological insulator-based Dirac hyperbolic metamaterial with large mode indices

TL;DR

This paper introduces a topological insulator-based hyperbolic metamaterial operating in the THz range, exhibiting extremely high mode indices and multiple volume plasmon polariton modes, promising advanced THz optical device integration.

Contribution

It demonstrates a novel Dirac hyperbolic metamaterial using topological insulators, achieving unprecedented mode indices and multiple VPP modes in the THz spectrum.

Findings

Up to three high-wavevector VPP modes observed.

Mode indices range from 126 to 531, much larger than traditional media.

Structures can be wafer-grown and integrated with existing THz devices.

Abstract

Hyperbolic metamaterials (HMMs) are engineered materials with a hyperbolic isofrequency surface, enabling a range of novel phenomena and applications including negative refraction, enhanced sensing, and subdiffraction imaging, focusing, and waveguiding. Existing HMMs primarily work in the visible and infrared spectral range due to the inherent properties of their constituent materials. Here we demonstrate a THz-range Dirac HMM using topological insulators (TIs) as the building blocks. We find that the structure houses up to three high-wavevector volume plasmon polariton (VPP) modes, consistent with transfer matrix modeling. The VPPs have mode indices ranging from 126 to 531, 10-100x larger than observed for VPP modes in traditional media while maintaining comparable quality factors. We attribute these properties to the two-dimensional Dirac nature of the electrons occupying the topological insulator surface states. Because these are van der Waals materials, these structures can be grown at a wafer-scale on a variety of substrates, allowing them to be integrated with existing THz structures and enabling next-generation THz optical devices.