Hole-based stealthy hyperuniform semiconductor computational metamaterials for the mid-infrared

Manuel Gallego; Sara Kacmoli; Yezhezi Zhang; Michael A. Klatt; Claire F. Gmachl

doi:10.1364/OE.559370

Hole-based stealthy hyperuniform semiconductor computational metamaterials for the mid-infrared

Manuel Gallego, Sara Kacmoli, Yezhezi Zhang, Michael A. Klatt, Claire F. Gmachl

Research output: Contribution to journal › Article › peer-review

Abstract

Stealthy-hyperuniform heterostructures are metamaterials with the potential for optical image processing at angles away from normal incidence. They show analogous properties to photonic crystals while circumventing the spatial anisotropy which often hinders the latter’s use. In this paper, we have designed, fabricated, and characterized a hole-based stealthy-hyperuniform structure on a quantum cascade layer substrate. The infrared spectral data reveal a sizable gap-midgap ratio of 10.4% for a photonic band gap around ∼12.0 µm in the form of an enhanced reflection region for increasing incidence angles. The stealthy hyperuniform metamaterial also showed spatial isotropy by its unchanging reflection spectrum for all in-plane rotational angle measurements.

Original language	English (US)
Pages (from-to)	31701-31712
Number of pages	12
Journal	Optics Express
Volume	33
Issue number	15
DOIs	https://doi.org/10.1364/OE.559370
State	Published - Jul 28 2025

All Science Journal Classification (ASJC) codes

Atomic and Molecular Physics, and Optics

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10.1364/OE.559370

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title = "Hole-based stealthy hyperuniform semiconductor computational metamaterials for the mid-infrared",

abstract = "Stealthy-hyperuniform heterostructures are metamaterials with the potential for optical image processing at angles away from normal incidence. They show analogous properties to photonic crystals while circumventing the spatial anisotropy which often hinders the latter{\textquoteright}s use. In this paper, we have designed, fabricated, and characterized a hole-based stealthy-hyperuniform structure on a quantum cascade layer substrate. The infrared spectral data reveal a sizable gap-midgap ratio of 10.4\% for a photonic band gap around ∼12.0 µm in the form of an enhanced reflection region for increasing incidence angles. The stealthy hyperuniform metamaterial also showed spatial isotropy by its unchanging reflection spectrum for all in-plane rotational angle measurements.",

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AU - Gallego, Manuel

AU - Kacmoli, Sara

AU - Zhang, Yezhezi

AU - Klatt, Michael A.

AU - Gmachl, Claire F.

PY - 2025/7/28

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AB - Stealthy-hyperuniform heterostructures are metamaterials with the potential for optical image processing at angles away from normal incidence. They show analogous properties to photonic crystals while circumventing the spatial anisotropy which often hinders the latter’s use. In this paper, we have designed, fabricated, and characterized a hole-based stealthy-hyperuniform structure on a quantum cascade layer substrate. The infrared spectral data reveal a sizable gap-midgap ratio of 10.4% for a photonic band gap around ∼12.0 µm in the form of an enhanced reflection region for increasing incidence angles. The stealthy hyperuniform metamaterial also showed spatial isotropy by its unchanging reflection spectrum for all in-plane rotational angle measurements.

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Hole-based stealthy hyperuniform semiconductor computational metamaterials for the mid-infrared

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