Finite-Difference Beam Propagation Method for Graphene-Based Devices

Author

Capobianco, Antonio-Daniele ; Locatelli, Andrea ; De Angelis, Costantino ; Boscolo, Stefano ; Midrio, Michele

Author_Institution

Dipt. di Ing. dell´Inf., Univ. degli Studi di Padova, Padua, Italy

Volume

26

Issue

10

fYear

2014

fDate

15-May-14

Firstpage

1007

Lastpage

1010

Abstract

We propose a novel finite-difference beam propagation method capable of dealing with the discontinuity of the tangential component of the magnetic field induced by bi-dimensional graphene layers, which can be arbitrarily placed within dielectric media. In stark contrast with conventional numerical solvers, this approach does not require a discretization step as small as a fraction of the atomic thickness of graphene, allowing ultrafast simulation times. The validity of the method is proved by propagating the plasmonic supermodes of two coupled graphene layers, and the evaluated beat length exhibits excellent agreement with respect to analytical results.

Keywords

dielectric materials; electro-optical devices; finite difference methods; graphene; laser beams; light propagation; permittivity; plasmonics; beat length; bidimensional graphene layers; dielectric media; finite-difference beam propagation method; graphene-based devices; plasmonic supermodes; tangential magnetic field component discontinuity; ultrafast simulation times; Chemicals; Couplers; Dielectrics; Graphene; Indexes; Optical waveguides; Plasmons; Graphene; beam propagation method; electro-optic devices; finite difference methods; plasmonics;

fLanguage

English

Journal_Title

Photonics Technology Letters, IEEE

Publisher

ieee

ISSN

1041-1135

Type

jour

DOI

10.1109/LPT.2014.2311173

Filename

6762839