# Hyperbolic Dispersion Dominant Regime Identified through Spontaneous   Emission Variations near Metamaterial Interfaces

**Authors:** Kwang Jin Lee, Yeon Ui Lee, Sang Jun Kim, Pascal Andr\'e

arXiv: 1701.05723 · 2018-01-30

## TL;DR

This study explores how hyperbolic metamaterials influence spontaneous emission properties of organic chromophores, revealing a dominant hyperbolic dispersion regime that affects emission lifetimes and offers insights for designing photonic surfaces.

## Contribution

It identifies the hyperbolic dispersion dominant regime as a key factor in spontaneous emission variations near HMM interfaces, advancing understanding of photonic control mechanisms.

## Key findings

- Spontaneous emission lifetimes vary non-monotonously near HMM interfaces.
- Emission lifetime is independent of the number of HMM pairs in certain regimes.
- Hyperbolic dispersion regime decreases emission lifetime.

## Abstract

Surface plasmon polariton, hyberbolic dispersion of energy and momentum, and emission interference provide opportunities to control photoluminescence properties. However, the interplays between these regimes need to be understood to take advantage of them in optoelectronic applications. Here, we investigate broadband variations induced by hyperbolic metamaterial (HMM) multilayer nanostructures on the spontaneous emission of selected organic chromophores. Experimental and calculated spontaneous emission lifetimes are shown to vary non-monotonously near HMM interfaces. With the SPP and interference dominant regimes. With the HMM number of pairs used as the analysis parameter, the lifetime is shown to be independent of the number of pairs in the surface plasmon polaritons, and emission interference dominant regimes, while it decreases in the Hyperbolic Dispersion dominant regime. We also show that the spontaneous emission lifetime is similarly affected by transverse positive and transverse negative HMMs. This work has broad implications on the rational design of functional photonic surfaces to control the luminescence of semiconductor chromophores.

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Source: https://tomesphere.com/paper/1701.05723