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Dynamically adjustable plasmon-induced transparency and switching application based on bilayer graphene metamaterials

Fengqi Zhou, Yuqing Wang, Xiao Zhang, Jiawei Wang, Zhimin Liu, Xin Luo, Zhenbin Zhang, Enduo Gao

2020Journal of Physics D Applied Physics46 citationsDOI

Abstract

Abstract A bilayer metamaterial composed of double graphene strips and square-ring graphene is proposed to realize plasmon induced transparency (PIT). The couple mode theory (CMT) is employed to explain the phenomenon of PIT, whose results are in good agreement with the simulation of the finite-difference time-domain. The dynamically adjustable PIT is investigated, where an on-to-off modulation composed of synchronous and asynchronous switching is realized by modulating the Fermi levels of graphene, the modulation degrees of amplitude are 67.5%, 86.1%, and 65.3%, respectively. The changes of transmission spectra are also studied by adjusting the coupling distance between double graphene strips and square-ring graphene, and the result shows that PIT is gradually disappeared with the increase of coupling distance and the decrease of coupling strength. Then, the corresponding relationships between dips of PIT and modes of CMT are described clearly, which are affected by the relative location between resonant points of the bright and dark modes.

Topics & Concepts

GrapheneMetamaterialSTRIPSModulation (music)PlasmonCoupling (piping)Slow lightCondensed matter physicsBilayerBilayer grapheneMaterials scienceAmplitude modulationAmplitudeCoupling strengthFermi energyOptoelectronicsOpticsPhysicsNanotechnologyFrequency modulationChemistryQuantum mechanicsTelecommunicationsPhotonic crystalElectronBandwidth (computing)Computer scienceBiochemistryAcousticsMembraneComposite materialMetallurgyPlasmonic and Surface Plasmon ResearchMetamaterials and Metasurfaces ApplicationsGold and Silver Nanoparticles Synthesis and Applications
Dynamically adjustable plasmon-induced transparency and switching application based on bilayer graphene metamaterials | Litcius