Tunable properties of omnidirectional band gap based on photonic quasicrystals containing superconducting material

Abstract

In this study, we report the transmittance properties of 1D superconducting photonic quasicrystals (SPQCs) with Generalized Fibonacci (GF) quasiperiodic sequence. The constituent heterolayers are made of dielectric (SiO2) and superconductor (YaBO2CuO7). The transmittance spectrum is theoretically investigated by the Transfer Matrix Method and the Gorter Casimir Two-fluid model. It is shown that the 1D SPQCs exhibit a broadening omnidirectional band gap (OBG) at given GF parameters. The photonic band gap was adjusted by the constituent materials properties and the sort of regular quasi-periodic\xa0arrangement of (H/L) layers. The bandwidth of OBG can be enhanced by applying a typical deformation along the basic 1D SPQC sample. Similarly, a significant enhancement of main gap can be\xa0achieved, covering an extremely\xa0broad\xa0range of\xa0visible\xa0light frequencies by juxtaposition of Fibonacci stacks (GF(m, n))p. By applying structural defects, a pointed insert peaks can be notably opened within the gap. These results may be useful for selective superconducting photonic high reflectors.