March 3, 2026

Hyperbolic dispersion and plasmon-polariton gap induced by off-diagonal anisotropy in photonic heterostructures

Key Points

The study reveals the presence of a plasmon-polariton gap at normal incidence in photonic heterostructures, which is pivotal for enhancing optical properties.
Investigation shows that tuning the frequency near the plasmon-polariton gap transforms the elliptic dispersion relation into hyperbolic dispersion.
Assessment using transfer matrix techniques provides insights into the effects of anisotropic metamaterials on dispersion within layered systems.
Highlights the importance of off-diagonal anisotropy, suggesting significant implications for future optical applications and material designs.

Abstract

The influence of the optical axis orientation on the features of the plasmon-polariton (PP) gap in photonic heterostructures is investigated. To this end a one-dimensional layered system embedded in vacuum and formed by stacking alternate layers of anisotropic metamaterial and air is thoroughly analyzed. Within the formalism of Maxwell's equations and transfer matrix techniques we show the existence of the PP-gap at normal incidence. Furthermore, by tuning the frequency of the incident wave in the neighborhood of this gap, the otherwise usual elliptic dispersion relation, becomes hyperbolic.

Hyperbolic dispersion and plasmon-polariton gap induced by off-diagonal anisotropy in photonic heterostructures

Key Points

Abstract

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