Stealthy and hyperuniform isotropic photonic band gap structure in 3D
Stealthy and hyperuniform isotropic photonic band gap structure in 3D
In photonic crystals the propagation of light is governed by their photonic band structure, an ensemble of propagating states grouped into bands, separated by photonic band gaps. Due to discrete symmetries in spatially strictly periodic dielectric structures their photonic band structure is intrinsically anisotropic. However, for many applications, such as manufacturing artificial structural color materials or developing photonic computing devices, but also for the fundamental understanding of light-matter interactions, it is of major interest to seek materials with long range non-periodic dielectric structures which allow the formation of {\it isotropic} photonic band gaps. Here, we report the first ever 3D isotropic photonic band gap for an optimized disordered stealthy hyperuniform structure for microwaves. The transmission spectra are directly compared to a diamond pattern and an amorphous structure with similar node density. The band structure is measured experimentally for all three microwave structures, manufactured by 3D-Laser-printing for meta-materials with refractive index up to $n=2.1$. Results agree well with finite-difference-time-domain numerical investigations and a priori calculations of the band-gap for the hyperuniform structure: the diamond structure shows gaps but being anisotropic as expected, the stealthy hyperuniform pattern shows an isotropic gap of very similar magnitude, while the amorphous structure does not show a gap at all. The centimeter scaled microwave structures may serve as prototypes for micrometer scaled structures with bandgaps in the technologically very interesting region of infrared (IR).
physics.app-ph, physics.optics
Siedentop, Lukas
7a2eb586-886f-45ff-b03e-5eb527ac963a
Lui, Gianluc
39b3788f-a47e-451f-a337-e8f43747bcc5
Maret, Georg
d43b8b1e-826c-4409-84b5-e3406f072aa7
Chaikin, Paul M.
efc9274e-226d-4414-b0c8-5c4ae5974ef7
Steinhardt, Paul J.
b5b5a024-4643-4446-9211-7587abc1c059
Torquato, Salvatore
55a42684-9a08-48fd-8720-a5f433de1d19
Keim, Peter
9944a4df-d082-4714-84eb-eddca8dac119
Florescu, Marian
14b7415d-9dc6-4ebe-a125-289e47648c65
6 September 2024
Siedentop, Lukas
7a2eb586-886f-45ff-b03e-5eb527ac963a
Lui, Gianluc
39b3788f-a47e-451f-a337-e8f43747bcc5
Maret, Georg
d43b8b1e-826c-4409-84b5-e3406f072aa7
Chaikin, Paul M.
efc9274e-226d-4414-b0c8-5c4ae5974ef7
Steinhardt, Paul J.
b5b5a024-4643-4446-9211-7587abc1c059
Torquato, Salvatore
55a42684-9a08-48fd-8720-a5f433de1d19
Keim, Peter
9944a4df-d082-4714-84eb-eddca8dac119
Florescu, Marian
14b7415d-9dc6-4ebe-a125-289e47648c65
Siedentop, Lukas, Lui, Gianluc, Maret, Georg, Chaikin, Paul M., Steinhardt, Paul J., Torquato, Salvatore, Keim, Peter and Florescu, Marian
(2024)
Stealthy and hyperuniform isotropic photonic band gap structure in 3D.
PNAS Nexus, 3 (9).
(doi:10.1093/pnasnexus/pgae383).
Abstract
In photonic crystals the propagation of light is governed by their photonic band structure, an ensemble of propagating states grouped into bands, separated by photonic band gaps. Due to discrete symmetries in spatially strictly periodic dielectric structures their photonic band structure is intrinsically anisotropic. However, for many applications, such as manufacturing artificial structural color materials or developing photonic computing devices, but also for the fundamental understanding of light-matter interactions, it is of major interest to seek materials with long range non-periodic dielectric structures which allow the formation of {\it isotropic} photonic band gaps. Here, we report the first ever 3D isotropic photonic band gap for an optimized disordered stealthy hyperuniform structure for microwaves. The transmission spectra are directly compared to a diamond pattern and an amorphous structure with similar node density. The band structure is measured experimentally for all three microwave structures, manufactured by 3D-Laser-printing for meta-materials with refractive index up to $n=2.1$. Results agree well with finite-difference-time-domain numerical investigations and a priori calculations of the band-gap for the hyperuniform structure: the diamond structure shows gaps but being anisotropic as expected, the stealthy hyperuniform pattern shows an isotropic gap of very similar magnitude, while the amorphous structure does not show a gap at all. The centimeter scaled microwave structures may serve as prototypes for micrometer scaled structures with bandgaps in the technologically very interesting region of infrared (IR).
Text
2403.08404v1
- Accepted Manuscript
More information
Accepted/In Press date: 23 August 2024
Published date: 6 September 2024
Additional Information:
9 pages, 6 figures
Keywords:
physics.app-ph, physics.optics
Identifiers
Local EPrints ID: 501234
URI: http://eprints.soton.ac.uk/id/eprint/501234
ISSN: 2752-6542
PURE UUID: f3e66890-6aaf-4b56-be9f-3e080811a8dc
Catalogue record
Date deposited: 27 May 2025 18:04
Last modified: 26 Jun 2025 02:16
Export record
Altmetrics
Contributors
Author:
Lukas Siedentop
Author:
Gianluc Lui
Author:
Georg Maret
Author:
Paul M. Chaikin
Author:
Paul J. Steinhardt
Author:
Salvatore Torquato
Author:
Peter Keim
Author:
Marian Florescu
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics