Controlling the absorption strength in bidirectional terahertz metamaterial absorbers with patterned graphene

Controlling the absorption strength in bidirectional terahertz metamaterial absorbers with patterned graphene

[Display omitted] •Demonstration of a THz graphene-integrated MMA that exhibit an exceptional absorption.•The proposed absorber allows significant transmission outside the absorption band.•The absorption strength is shown to be systematically tunable between 41% and 91%.•The tunability mechanism is...

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Bibliographic Details
Published in:Computational materials science Vol. 166; pp. 276 - 281
Main Authors: Van Huynh, Tran, Tung, Bui Son, Khuyen, Bui Xuan, Ngo, Son Tung, Lam, Vu Dinh, Tung, Nguyen Thanh
Format: Journal Article
Language:English
Published: Elsevier B.V 01-08-2019
Subjects:
Graphene
Perfect absorbers
Tunable metamaterials
Graphene
Perfect absorbers
Tunable metamaterials
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Summary:[Display omitted] •Demonstration of a THz graphene-integrated MMA that exhibit an exceptional absorption.•The proposed absorber allows significant transmission outside the absorption band.•The absorption strength is shown to be systematically tunable between 41% and 91%.•The tunability mechanism is explained by the response of the graphene’s conductivity to the applied bias voltage.•The proposed absorber can function like a bidirectional switchable absorption window. THz metamaterials that exhibit excellent absorption properties with real-time tunability have been of great interest for various applications. In this paper, we combine symmetric metamaterials and patterned graphene to achieve an electrically-switchable bidirectional absorption window operating in terahertz frequencies. The proposed metamaterial can homogeneously absorb the incident waves while allowing significant transmission outside the absorption band. Our simulations show that the tunable electrical conductivity of the patterned graphene can result in a desired control of the absorptivity between 41% and 91%. Finite integration simulations, standard retrieval procedure, equivalent circuit model, and effective medium analysis are employed to elaborate our idea.
ISSN:0927-0256
1879-0801
DOI:10.1016/j.commatsci.2019.05.011