# Tunable Hyperbolic Metamaterials Based on Self-Assembled Carbon   Nanotubes

**Authors:** John Andris Roberts, Shang-Jie Yu, Po-Hsun Ho, Stefan Schoeche, Abram, L. Falk, and Jonathan A. Fan

arXiv: 1903.11140 · 2019-03-28

## TL;DR

This paper demonstrates that self-assembled, aligned carbon nanotube films act as tunable hyperbolic metamaterials with ultra-small unit cells, supporting strong light localization and broadband tunability in the mid-infrared range.

## Contribution

It introduces a method to create tunable hyperbolic metamaterials using self-assembled carbon nanotubes with detailed optical characterization and theoretical modeling.

## Key findings

- Broadband hyperbolic region tunable in mid-infrared
- Strong light localization in hyperbolic plasmon modes
- Agreement between experiments and models confirms anisotropic nanoscale response

## Abstract

We show that packed, horizontally aligned films of single-walled carbon nanotubes are hyperbolic metamaterials with ultra-subwavelength unit cells and dynamic tunability. Using Mueller-matrix ellipsometry, we characterize the films' doping-level dependent optical properties and find a broadband hyperbolic region tunable in the mid-infrared. To characterize the dispersion of in-plane hyperbolic plasmon modes, we etch the nanotube films into nanoribbons with differing widths and orientations relative to the nanotube axis, and we observe that the hyperbolic modes support strong light localization. Agreement between the experiments and theoretical models using the ellipsometry data indicates that the packed carbon nanotubes support bulk anisotropic responses at the nanoscale. Self-assembled films of carbon nanotubes are well suited for applications in thermal emission and photodetection, and they serve as model systems for studying light-matter interactions in the deep subwavelength regime.

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Source: https://tomesphere.com/paper/1903.11140