Tuning of magnetosplamon coupling between graphene scatterers for the optimal design of adjustable metasurfaces

Tuning of magnetosplamon coupling between graphene scatterers for the optimal design of adjustable metasurfaces

The resonance characteristics of magnetically-biased graphene micro-scatterers are thoroughly investigated in the present work using both eigenvalue and full-wave solvers. Initially, the graphene surface conductivity is presented in a tensor form due to the application of a magnetostatic bias field,...

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Veröffentlicht in:AIP advances 2024-02, Vol.14 (2), p.025225-025225-5
Hauptverfasser: Amanatiadis, Stamatios, Ohtani, Tadao, Kanai, Yasushi, Kantartzis, Nikolaos
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Sprache:eng
Schlagworte:
Absorption cross sections
Bias
Coupling
Eigenvalues
Finite difference time domain method
Graphene
Metasurfaces
Modal analysis
Plane waves
Plasmonics
Resonant frequencies
Tensors
Wave propagation
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creator Amanatiadis, Stamatios
Ohtani, Tadao
Kanai, Yasushi
Kantartzis, Nikolaos
description The resonance characteristics of magnetically-biased graphene micro-scatterers are thoroughly investigated in the present work using both eigenvalue and full-wave solvers. Initially, the graphene surface conductivity is presented in a tensor form due to the application of a magnetostatic bias field, which is perpendicular to the material’s surface. Then, the simple case of a graphene disk scatterer is examined, and a properly modified eigenvalue formulation is utilized to extract the plasmonic fundamental frequencies. The validity of the modal analysis is verified via a full-wave analysis that involves a plane-wave propagation and the extraction of the subsequent absorption cross-section utilizing the Finite-Difference Time-Domain method. Additionally, the dependence of a single disk scatterer resonances with the magnetostatic bias is evaluated, highlighting that as the bias field is increased, every edge mode degenerates into two sub-modes with an augmented difference between the resonant frequencies. Finally, the plasmonic coupling between adjacent scatterers is studied considering a periodic arrangement, similar to a metasurface, indicating the additional coupling modes as well as the adjustability of the properties with multiple degrees of freedom.
doi_str_mv 10.1063/9.0000808
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subjects Absorption cross sections
Bias
Coupling
Eigenvalues
Finite difference time domain method
Graphene
Metasurfaces
Modal analysis
Plane waves
Plasmonics
Resonant frequencies
Tensors
Wave propagation
title Tuning of magnetosplamon coupling between graphene scatterers for the optimal design of adjustable metasurfaces
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