Actively programmable MEMS-based racetrack-shaped terahertz metamaterial

We present four designs of actively tunable micro-electro-mechanical system-based racetrack-shaped metamaterials (RSMs), which are denoted as RSM_1, RSM_2, RSM_3, and RSM_4, respectively. RSM_1 is composed of asymmetrically single RSM, while RSM_2, RSM_3, and RSM_4 are all composed of asymmetrically...

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Published inJournal of applied physics Vol. 131; no. 11
Main Authors Fu, Yuping, Xu, Xiaocan, Lin, Yu-Sheng
Format Journal Article
LanguageEnglish
Published Melville American Institute of Physics 21.03.2022
Subjects
Applied physics
Asymmetry
Magnetic resonance
Metamaterials
Microelectromechanical systems
Optical switching
Polarization
Programmable logic devices
Resonance
Transverse electric modes
Transverse magnetic modes
Wireless communications
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Abstract We present four designs of actively tunable micro-electro-mechanical system-based racetrack-shaped metamaterials (RSMs), which are denoted as RSM_1, RSM_2, RSM_3, and RSM_4, respectively. RSM_1 is composed of asymmetrically single RSM, while RSM_2, RSM_3, and RSM_4 are all composed of asymmetrically double RSM layers with different rotation angles of 0°, 90°, and 180°, respectively. RSM_1 exhibits single-resonance in the transverse electric mode and dual-resonance in the transverse magnetic mode to perform the polarization-dependent characteristic. RSM_2, RSM_3, and RSM_4 exhibit tunable multi-resonance characteristics. By changing the height of the suspended layer, RSM_2, RSM_3, and RSM_4 exhibit optical switching characteristics. These switching resonances can be equivalent to binary bits, i.e., “0” and “1,” which can be programmed for opto-logic applications. These four designs of RSM devices possess the programmable multidigit switching characteristic by changing the incident polarization light. This study provides the possibility of a terahertz metamaterial to be used in the switch, programmable device, radar, and optical wireless communication applications.
AbstractList We present four designs of actively tunable micro-electro-mechanical system-based racetrack-shaped metamaterials (RSMs), which are denoted as RSM_1, RSM_2, RSM_3, and RSM_4, respectively. RSM_1 is composed of asymmetrically single RSM, while RSM_2, RSM_3, and RSM_4 are all composed of asymmetrically double RSM layers with different rotation angles of 0°, 90°, and 180°, respectively. RSM_1 exhibits single-resonance in the transverse electric mode and dual-resonance in the transverse magnetic mode to perform the polarization-dependent characteristic. RSM_2, RSM_3, and RSM_4 exhibit tunable multi-resonance characteristics. By changing the height of the suspended layer, RSM_2, RSM_3, and RSM_4 exhibit optical switching characteristics. These switching resonances can be equivalent to binary bits, i.e., “0” and “1,” which can be programmed for opto-logic applications. These four designs of RSM devices possess the programmable multidigit switching characteristic by changing the incident polarization light. This study provides the possibility of a terahertz metamaterial to be used in the switch, programmable device, radar, and optical wireless communication applications.
Author Xu, Xiaocan
Fu, Yuping
Lin, Yu-Sheng
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Snippet We present four designs of actively tunable micro-electro-mechanical system-based racetrack-shaped metamaterials (RSMs), which are denoted as RSM_1, RSM_2,...
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SubjectTerms Applied physics
Asymmetry
Magnetic resonance
Metamaterials
Microelectromechanical systems
Optical switching
Polarization
Programmable logic devices
Resonance
Transverse electric modes
Transverse magnetic modes
Wireless communications
Title Actively programmable MEMS-based racetrack-shaped terahertz metamaterial
URI http://dx.doi.org/10.1063/5.0069625
https://www.proquest.com/docview/2640144151
Volume 131
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