Tunable 1D nano-photonic filter using Nematic liquid crystal and high-Tc superconductors

被引:0
作者
Y. Trabelsi
N. Ben Ali
Francis Segovia-Chaves
Herbert Vinck Posada
机构
[1] King Khalid University,Physics Department, College of Arts and Sciences in Muhail Asir
[2] University of Ha’il,Departments of Industrial Engineering, College of Engineering
[3] University of Tunis El Manar,Photovoltaic and Semiconductor Materials Laboratory, National Engineering School of Tunis
[4] Universidad Surcolombiana,Grupo de Física Teórica, Programa de Física
[5] Universidad Nacional de Colombia,Grupo de superconductividad y Nanotecnología, Departmento de física
来源
Optical and Quantum Electronics | 2021年 / 53卷
关键词
Photonic crystals; Superconducting materials; Nematic liquid crystals; Optical materials;
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摘要
In this paper, the properties of hybrid photonic band gaps (PBGs) has been theoretically investigated using the transfer matrix method (TMM) and Gorter Casimir two-fluid model. These 1D photonic quasicrystals are built using the hybrid materials (Bi,Pb)2Sr2Ca2Cu3Ox/anisotropic Nematic liquid crystal layers. Based on the simulation results, a tunable PBG can be achieved within the transmission spectrum with sub comb-like resonant peaks at regular temperature of high Tc superconductor. The PBG properties and the number of resonant peaks are directly modulated by the superconductor temperature, the thickness of the dielectric layers and the lattice parameters of the quasi-periodic structure. In addition, the dependence of the PBGs on the temperature of the Nematic liquid crystal is discussed. The behavior of PBGs undergoing mechanical deformation for both polarization modes and in the presence of an external applied voltage is discussed. These structures can serve as tunable optical stop-band-gap-filters in photonic integrated circuits.
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