Propagação de ondas eletromagnéticas em quasicristais de Kolakoski com grafeno

In this work, we simulate the incidence of electromagnetic waves in an one-dimensional photonic quasicrystal composed of multilayers following the Kolakoski sequence with graphene embedded at the interface between different media. The system is formed by the juxtaposition of two blocks of different...

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Detalhes bibliográficos
Autor: Feitosa, Francisco Alexandre de Oliveira
Formato: tesis doctoral
Estado:Versión publicada
Fecha de publicación:2021
País:Brasil
Recursos:Universidade Federal do Rio Grande do Norte (UFRN)
Repositorio:Repositório Institucional da UFRN
Idioma:portugués
OAI Identifier:oai:repositorio.ufrn.br:123456789/47034
Acesso em linha:https://repositorio.ufrn.br/handle/123456789/47034
Access Level:acceso abierto
Palavra-chave:Física
Quasicristais fotônicos
Grafeno
Sequência de Kolakoski
Descrição
Resumo:In this work, we simulate the incidence of electromagnetic waves in an one-dimensional photonic quasicrystal composed of multilayers following the Kolakoski sequence with graphene embedded at the interface between different media. The system is formed by the juxtaposition of two blocks of different dielectric materials, A and B, with A being silicon dioxide, (SiO2) and B being titanium dioxide, (T iO2). Between the blocks A and B we insert layers of graphene. We used the Transfer Matrix Method, which simplifies the algebra involved, to perform the numerical calculation that generated the data analyzed in this work. Next, we present the objectives of this work: generate the necessary data to establish the transmission and reflection spectra, investigate the effects of the graphene monolayer and evaluate the effects of the quasiperiodicity on the physical behavior of the system. To do so, we impose variations on the following parameters of the system: angle of incidence, chemical potential of graphene, Kolakoski generation index and the type of electromagnetic propagation mode. The results obtained reveal that the presence of graphene reduces the transmissivity across the entire frequency range and also induces a band gap in the low frequency transmission. Furthermore, we observe that the band gap produced by graphene is omnidirectional and that its thickness increases with the increase of graphene’s chemical potential, which can be adjusted by the value of the electrical voltage. Furthermore, we identified frequency ranges that present Bragg band gaps.