Electrically Tunable Slow Light Using Graphene Metamaterials

Teun Teun Kim; Hyeon Don Kim; Rongkuo Zhao; Sang Soon Oh; Taewoo Ha; Dong Seob Chung; Young Hee Lee; Bumki Min; Shuang Zhang

doi:10.1021/acsphotonics.7b01551

Electrically Tunable Slow Light Using Graphene Metamaterials

Teun Teun Kim
, Hyeon Don Kim
, Rongkuo Zhao
, Sang Soon Oh
, Taewoo Ha
, Dong Seob Chung
, Young Hee Lee
, Bumki Min
, Shuang Zhang

Department of Physics

Institute for Basic Science
Sungkyunkwan University
Korea Advanced Institute of Science and Technology
University of California at Berkeley
Cardiff University
University of Birmingham

Research output: Contribution to journal › Article › peer-review

238 Scopus citations

Abstract

Metamaterials with classical analogues of electromagnetically induced transparency open new avenues in photonics for realizing smaller, more efficient slow light devices without quantum approaches. However, most of the metamaterial-based slow light devices are passive, which limits their practical applications. Here, by combining diatomic metamaterials with a gated single-layer graphene, we demonstrate that the group delay of terahertz light can be dynamically controlled under a small gate voltage. Using a two coupled harmonic oscillators model, we show that this active control of group delay is made possible by an effective control of the dissipative loss of the radiative dark resonator by varying the graphene's optical conductivity. Our work may provide opportunities in the design of various applications such as compact slow light devices and ultrasensitive sensors and switches.

Original language	English
Pages (from-to)	1800-1807
Number of pages	8
Journal	ACS Photonics
Volume	5
Issue number	5
DOIs	https://doi.org/10.1021/acsphotonics.7b01551
State	Published - 16 May 2018

Keywords

electromagnetically induced transparency
graphene
metamaterial
slow light
terahertz

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10.1021/acsphotonics.7b01551

Cite this

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title = "Electrically Tunable Slow Light Using Graphene Metamaterials",

abstract = "Metamaterials with classical analogues of electromagnetically induced transparency open new avenues in photonics for realizing smaller, more efficient slow light devices without quantum approaches. However, most of the metamaterial-based slow light devices are passive, which limits their practical applications. Here, by combining diatomic metamaterials with a gated single-layer graphene, we demonstrate that the group delay of terahertz light can be dynamically controlled under a small gate voltage. Using a two coupled harmonic oscillators model, we show that this active control of group delay is made possible by an effective control of the dissipative loss of the radiative dark resonator by varying the graphene's optical conductivity. Our work may provide opportunities in the design of various applications such as compact slow light devices and ultrasensitive sensors and switches.",

keywords = "electromagnetically induced transparency, graphene, metamaterial, slow light, terahertz",

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AU - Kim, Teun Teun

AU - Kim, Hyeon Don

AU - Zhao, Rongkuo

AU - Oh, Sang Soon

AU - Ha, Taewoo

AU - Chung, Dong Seob

AU - Lee, Young Hee

AU - Min, Bumki

AU - Zhang, Shuang

PY - 2018/5/16

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AB - Metamaterials with classical analogues of electromagnetically induced transparency open new avenues in photonics for realizing smaller, more efficient slow light devices without quantum approaches. However, most of the metamaterial-based slow light devices are passive, which limits their practical applications. Here, by combining diatomic metamaterials with a gated single-layer graphene, we demonstrate that the group delay of terahertz light can be dynamically controlled under a small gate voltage. Using a two coupled harmonic oscillators model, we show that this active control of group delay is made possible by an effective control of the dissipative loss of the radiative dark resonator by varying the graphene's optical conductivity. Our work may provide opportunities in the design of various applications such as compact slow light devices and ultrasensitive sensors and switches.

KW - electromagnetically induced transparency

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KW - metamaterial

KW - slow light

KW - terahertz

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Electrically Tunable Slow Light Using Graphene Metamaterials

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Keywords

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