Mechanically reconfigurable multi-functional meta-optics studied at microwave frequencies

Mechanically reconfigurable multi-functional meta-optics studied at microwave frequencies

Abstract Metasurfaces advanced the field of optics by reducing the thickness of optical components and merging multiple functionalities into a single layer device. However, this generally comes with a reduction in performance, especially for multi-functional and broadband applications. Three-dimensi...

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Main Authors: Conner Ballew, Gregory Roberts, Sarah Camayd-Muñoz, Maximilien F. Debbas, Andrei Faraon
Format: Article
Language:English
Published: Nature Publishing Group 2021-05-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-021-88785-5
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spelling doaj-dac517fab0e342e5ababaa84ed05b9612021-05-30T11:40:18ZengNature Publishing GroupScientific Reports2045-23222021-05-011111910.1038/s41598-021-88785-5Mechanically reconfigurable multi-functional meta-optics studied at microwave frequenciesConner Ballew0Gregory Roberts1Sarah Camayd-Muñoz2Maximilien F. Debbas3Andrei Faraon4Kavli Nanoscience Institute and Thomas J. Watson Sr. Laboratory of Applied Physics, California Institute of TechnologyKavli Nanoscience Institute and Thomas J. Watson Sr. Laboratory of Applied Physics, California Institute of TechnologyKavli Nanoscience Institute and Thomas J. Watson Sr. Laboratory of Applied Physics, California Institute of TechnologyKavli Nanoscience Institute and Thomas J. Watson Sr. Laboratory of Applied Physics, California Institute of TechnologyKavli Nanoscience Institute and Thomas J. Watson Sr. Laboratory of Applied Physics, California Institute of TechnologyAbstract Metasurfaces advanced the field of optics by reducing the thickness of optical components and merging multiple functionalities into a single layer device. However, this generally comes with a reduction in performance, especially for multi-functional and broadband applications. Three-dimensional metastructures can provide the necessary degrees of freedom for advanced applications, while maintaining minimal thickness. This work explores mechanically reconfigurable devices that perform focusing, spectral demultiplexing, and polarization sorting based on mechanical configuration. As proof of concept, a rotatable device, a device based on rotating squares, and a shearing-based device are designed with adjoint-based topology optimization, 3D-printed, and measured at microwave frequencies (7.6–11.6 GHz) in an anechoic chamber.https://doi.org/10.1038/s41598-021-88785-5
collection DOAJ
language English
format Article
sources DOAJ
author Conner Ballew
Gregory Roberts
Sarah Camayd-Muñoz
Maximilien F. Debbas
Andrei Faraon
spellingShingle Conner Ballew
Gregory Roberts
Sarah Camayd-Muñoz
Maximilien F. Debbas
Andrei Faraon
Mechanically reconfigurable multi-functional meta-optics studied at microwave frequencies
Scientific Reports
author_facet Conner Ballew
Gregory Roberts
Sarah Camayd-Muñoz
Maximilien F. Debbas
Andrei Faraon
author_sort Conner Ballew
title Mechanically reconfigurable multi-functional meta-optics studied at microwave frequencies
title_short Mechanically reconfigurable multi-functional meta-optics studied at microwave frequencies
title_full Mechanically reconfigurable multi-functional meta-optics studied at microwave frequencies
title_fullStr Mechanically reconfigurable multi-functional meta-optics studied at microwave frequencies
title_full_unstemmed Mechanically reconfigurable multi-functional meta-optics studied at microwave frequencies
title_sort mechanically reconfigurable multi-functional meta-optics studied at microwave frequencies
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2021-05-01
description Abstract Metasurfaces advanced the field of optics by reducing the thickness of optical components and merging multiple functionalities into a single layer device. However, this generally comes with a reduction in performance, especially for multi-functional and broadband applications. Three-dimensional metastructures can provide the necessary degrees of freedom for advanced applications, while maintaining minimal thickness. This work explores mechanically reconfigurable devices that perform focusing, spectral demultiplexing, and polarization sorting based on mechanical configuration. As proof of concept, a rotatable device, a device based on rotating squares, and a shearing-based device are designed with adjoint-based topology optimization, 3D-printed, and measured at microwave frequencies (7.6–11.6 GHz) in an anechoic chamber.
url https://doi.org/10.1038/s41598-021-88785-5
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AT gregoryroberts mechanicallyreconfigurablemultifunctionalmetaopticsstudiedatmicrowavefrequencies
AT sarahcamaydmunoz mechanicallyreconfigurablemultifunctionalmetaopticsstudiedatmicrowavefrequencies
AT maximilienfdebbas mechanicallyreconfigurablemultifunctionalmetaopticsstudiedatmicrowavefrequencies
AT andreifaraon mechanicallyreconfigurablemultifunctionalmetaopticsstudiedatmicrowavefrequencies
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