Saved in:
Bibliographic Details
Main Authors: Magnusson, Robert, Ko, Yeong H., Lee, Kyu J., Simlan, Fairooz A., Bootpakdeetam, Pawarat, Chen, Renjie, Weidanz, Debra Wawro, Gimlin, Susanne, Ghaffari, Soroush
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2404.13167
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916215028449280
author Magnusson, Robert
Ko, Yeong H.
Lee, Kyu J.
Simlan, Fairooz A.
Bootpakdeetam, Pawarat
Chen, Renjie
Weidanz, Debra Wawro
Gimlin, Susanne
Ghaffari, Soroush
author_facet Magnusson, Robert
Ko, Yeong H.
Lee, Kyu J.
Simlan, Fairooz A.
Bootpakdeetam, Pawarat
Chen, Renjie
Weidanz, Debra Wawro
Gimlin, Susanne
Ghaffari, Soroush
contents We present subwavelength resonant lattices fashioned as nano- and microstructured films as a basis for a host of device concepts. Whereas the canonical physical properties are fully embodied in a one-dimensional periodic lattice, the final device constructs are often patterned in two-dimensionally-modulated films in which case we may refer to them as photonic crystal slabs, metamaterials, or metasurfaces. These surfaces can support lateral modes and localized field signatures with propagative and evanescent diffraction channels critically controlling the response. The governing principle of guided-mode, or lattice, resonance enables diverse spectral expressions such that a single-layer component can behave as a sensor, reflector, filter, or polarizer. This structural sparsity contrasts strongly with the venerable field of multi-layer thin-film optics that is basis for most optical components on the market today. The lattice resonance effect can be exploited in all major spectral regions with appropriate low-loss materials and fabrication resources. In this paper, we highlight resonant device technology and present our work on design, fabrication, and characterization of optical elements operating in the near-IR, mid-IR, and long-wave IR spectral regions. Examples of fabricated and tested devices include biological sensors, high-contrast-ratio polarizers, narrow-band notch filters, and wideband high reflectors.
format Preprint
id arxiv_https___arxiv_org_abs_2404_13167
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Infrared resonance-lattice device technology
Magnusson, Robert
Ko, Yeong H.
Lee, Kyu J.
Simlan, Fairooz A.
Bootpakdeetam, Pawarat
Chen, Renjie
Weidanz, Debra Wawro
Gimlin, Susanne
Ghaffari, Soroush
Optics
We present subwavelength resonant lattices fashioned as nano- and microstructured films as a basis for a host of device concepts. Whereas the canonical physical properties are fully embodied in a one-dimensional periodic lattice, the final device constructs are often patterned in two-dimensionally-modulated films in which case we may refer to them as photonic crystal slabs, metamaterials, or metasurfaces. These surfaces can support lateral modes and localized field signatures with propagative and evanescent diffraction channels critically controlling the response. The governing principle of guided-mode, or lattice, resonance enables diverse spectral expressions such that a single-layer component can behave as a sensor, reflector, filter, or polarizer. This structural sparsity contrasts strongly with the venerable field of multi-layer thin-film optics that is basis for most optical components on the market today. The lattice resonance effect can be exploited in all major spectral regions with appropriate low-loss materials and fabrication resources. In this paper, we highlight resonant device technology and present our work on design, fabrication, and characterization of optical elements operating in the near-IR, mid-IR, and long-wave IR spectral regions. Examples of fabricated and tested devices include biological sensors, high-contrast-ratio polarizers, narrow-band notch filters, and wideband high reflectors.
title Infrared resonance-lattice device technology
topic Optics
url https://arxiv.org/abs/2404.13167