Broadband Terahertz Transparency in a Switchable Metasurface

Broadband Terahertz Transparency in a Switchable Metasurface

Plasmon-induced transparency in terahertz metamaterials markedly modifies the dispersive properties of an otherwise opaque medium and reveals unprecedented prospects on novel functional components. However, plasmon-induced transparency in metamaterials so far exists in a narrow frequency band or wit...

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Main Authors: Xiaoqiang Su, Chunmei Ouyang, Ningning Xu, Siyu Tan, Jianqiang Gu, Zhen Tian, Jiaguang Han, Fengping Yan, Weili Zhang
Format: Article
Language:English
Published: IEEE 2015-01-01
Series:IEEE Photonics Journal
Subjects:
Metamaterials
optical manipulation
metasurface
plasmon induced transparency
Online Access:https://ieeexplore.ieee.org/document/7008493/
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spelling doaj-ac8d86ba6c7b42ec99374be30d7a52d82021-03-29T17:21:22ZengIEEEIEEE Photonics Journal1943-06552015-01-01711810.1109/JPHOT.2015.23901467008493Broadband Terahertz Transparency in a Switchable MetasurfaceXiaoqiang Su0Chunmei Ouyang1Ningning Xu2Siyu Tan3Jianqiang Gu4Zhen Tian5Jiaguang Han6Fengping Yan7Weili Zhang8Key Lab. of Optoelectron. Inf. & Technol., Tianjin Univ., Tianjin, ChinaKey Lab. of Optoelectron. Inf. & Technol., Tianjin Univ., Tianjin, ChinaSch. of Electr. & Comput. Eng., Oklahoma State Univ., Stillwater, OK, USASch. of Electr. & Comput. Eng., Oklahoma State Univ., Stillwater, OK, USAKey Lab. of Optoelectron. Inf. & Technol., Tianjin Univ., Tianjin, ChinaKey Lab. of Optoelectron. Inf. & Technol., Tianjin Univ., Tianjin, ChinaKey Lab. of Optoelectron. Inf. & Technol., Tianjin Univ., Tianjin, ChinaKey Lab. of All Opt. Network & Adv. Telecommun. Network of EMC, Beijing Jiaotong Univ., Beijing, ChinaKey Lab. of Optoelectron. Inf. & Technol., Tianjin Univ., Tianjin, ChinaPlasmon-induced transparency in terahertz metamaterials markedly modifies the dispersive properties of an otherwise opaque medium and reveals unprecedented prospects on novel functional components. However, plasmon-induced transparency in metamaterials so far exists in a narrow frequency band or without actively tunable abilities. Here, we demonstrate optical control of a broadband plasmon-induced transparency in a hybrid metamaterial made from integrated silicon-metal unit cells. Attributed to the modification in damping rate of the dark mode resonators under optical excitation, a giant dynamic amplitude modulation of the broadband transparency window is observed. The scheme suggested here is promising in developing broadband active slow-light devices and realizing on-to-off switching responses of the terahertz radiation at room temperature.https://ieeexplore.ieee.org/document/7008493/Metamaterialsoptical manipulationmetasurfaceplasmon induced transparency
collection DOAJ
language English
format Article
sources DOAJ
author Xiaoqiang Su
Chunmei Ouyang
Ningning Xu
Siyu Tan
Jianqiang Gu
Zhen Tian
Jiaguang Han
Fengping Yan
Weili Zhang
spellingShingle Xiaoqiang Su
Chunmei Ouyang
Ningning Xu
Siyu Tan
Jianqiang Gu
Zhen Tian
Jiaguang Han
Fengping Yan
Weili Zhang
Broadband Terahertz Transparency in a Switchable Metasurface
IEEE Photonics Journal
Metamaterials
optical manipulation
metasurface
plasmon induced transparency
author_facet Xiaoqiang Su
Chunmei Ouyang
Ningning Xu
Siyu Tan
Jianqiang Gu
Zhen Tian
Jiaguang Han
Fengping Yan
Weili Zhang
author_sort Xiaoqiang Su
title Broadband Terahertz Transparency in a Switchable Metasurface
title_short Broadband Terahertz Transparency in a Switchable Metasurface
title_full Broadband Terahertz Transparency in a Switchable Metasurface
title_fullStr Broadband Terahertz Transparency in a Switchable Metasurface
title_full_unstemmed Broadband Terahertz Transparency in a Switchable Metasurface
title_sort broadband terahertz transparency in a switchable metasurface
publisher IEEE
series IEEE Photonics Journal
issn 1943-0655
publishDate 2015-01-01
description Plasmon-induced transparency in terahertz metamaterials markedly modifies the dispersive properties of an otherwise opaque medium and reveals unprecedented prospects on novel functional components. However, plasmon-induced transparency in metamaterials so far exists in a narrow frequency band or without actively tunable abilities. Here, we demonstrate optical control of a broadband plasmon-induced transparency in a hybrid metamaterial made from integrated silicon-metal unit cells. Attributed to the modification in damping rate of the dark mode resonators under optical excitation, a giant dynamic amplitude modulation of the broadband transparency window is observed. The scheme suggested here is promising in developing broadband active slow-light devices and realizing on-to-off switching responses of the terahertz radiation at room temperature.
topic Metamaterials
optical manipulation
metasurface
plasmon induced transparency
url https://ieeexplore.ieee.org/document/7008493/
work_keys_str_mv AT xiaoqiangsu broadbandterahertztransparencyinaswitchablemetasurface
AT chunmeiouyang broadbandterahertztransparencyinaswitchablemetasurface
AT ningningxu broadbandterahertztransparencyinaswitchablemetasurface
AT siyutan broadbandterahertztransparencyinaswitchablemetasurface
AT jianqianggu broadbandterahertztransparencyinaswitchablemetasurface
AT zhentian broadbandterahertztransparencyinaswitchablemetasurface
AT jiaguanghan broadbandterahertztransparencyinaswitchablemetasurface
AT fengpingyan broadbandterahertztransparencyinaswitchablemetasurface
AT weilizhang broadbandterahertztransparencyinaswitchablemetasurface
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