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Dynamically Tunable Electromagnetically Induced Transparency-Like Effect in Terahertz Metamaterial Based on Graphene Cross Structures

Mingming Chen, Zhongyin Xiao, Fei Lv, Zhentao Cui, Qidi Xu

2021IEEE Journal of Selected Topics in Quantum Electronics25 citationsDOI

Abstract

A simple and multi-layer metamaterial made of graphene to realize excellent manipulation of EIT-like effect is proposed. The unit cell consists of four layers: Substrate 1, Cross 1, Substrate 2 and Cross 2, which can obtain tunable EIT-like effect by adjusting the Fermi level of graphene. The surface current distributions of four different views clearly explain the underlying physical mechanism. A three-level Λ-type system is employed to describe the coupling process between Cross 1 and 2. The calculated transmission spectra based on two-particle model have great agreement with the simulated transmission spectra. In addition, the effects of geometrical parameters on EIT-like effect are discussed and wideband EIT-like effect with high transmission can be obtained by adjusting the lengths of Cross 1 and 2. Also, the polarization-insensitive character of EIT-like metamaterial is confirmed by the transmission spectra under different polarization angles. The maximum of group delay (25.48 ps) is far greater than the group delay of previously reported EIT-like metamaterials. Our study provides a novel way for the development of slow-light devices and modulators.

Topics & Concepts

Electromagnetically induced transparencyMetamaterialTerahertz radiationGroup delay and phase delaySlow lightOptoelectronicsPolarization (electrochemistry)GrapheneOpticsMaterials scienceCoupling (piping)Spectral linePhysicsPhotonic crystalBandwidth (computing)TelecommunicationsNanotechnologyComputer scienceMetallurgyAstronomyPhysical chemistryChemistryMetamaterials and Metasurfaces ApplicationsPlasmonic and Surface Plasmon ResearchTerahertz technology and applications
Dynamically Tunable Electromagnetically Induced Transparency-Like Effect in Terahertz Metamaterial Based on Graphene Cross Structures | Litcius