Plazma Tipi Malzeme İçeren Fotonik Kristal Yapıların Tasarımı
Date
2024Author
Engin Kıraç, Ezgi
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Plasma photonic crystal (PFC) structure is created by arranging a material exhibiting
both dielectric and plasma properties in a multilayered manner according to different
sequences. This thesis study focuses on the design of plasma photonic crystal
structures with specific sequences that can be used in various optical applications, and
investigates their reflection, transmission and absorption behaviors. In the designed
structures, the first section employs homogeneous, non-magnetized, weakly ionized
plasma material. In the second section, magnetized plasma material is used to create
new designs. The Transfer Matrix Method (TMM) is employed in this study, and its
formulation is provided.
After confirming the results of similar studies in the literature, four different PFC’s are
designed using periodic sequences, Fibonacci, Thue-Morse and Cantor series. These
designs are expanded to include and exclude defect layers. Air and different dielectric
materials are chosen as defect layers. For each of PFC structures, the effects of
plasma electron density, defect layer dielectric constant and thickness on reflection
and transmission behaviors are examined in the first section. Additionally, for the
magnetized PFC structure, new parameters such as external magnetic field and
collision frequency are also analyzed to determined reflection, transmission, and
absorption behaviors, specifically for periodic and Cantor series-based designs.
In the literature, it is reported that PFC designs based on periodic, Fibonacci, Thue-
Morse and Cantor sequences exhibit distinct characteristics in terms of optical
reflection, transmission, and absorption behaviors. This thesis investigates the
comparative contributions of these structures to PFC design by considering various
structural parameters together. Periodic PFC forms result with multi-channel
transmission characteristic. Fibonacci Sequence PFC yields high reflection at low
frequencies and creates a multi-channel structure at high frequencies. Thue-Morse
Sequence PFC is primarily suited for single-channel transmission but exhibits high
reflection outside the transmission region. Cantor Sequence PFC uniquely displays
broader transmission behavior compared to the others. For magnetized plasma,
similar characteristics emerge, with both periodic and Cantor sequence-based
structures exhibiting increased transmission bandwidths. These findings highlight the
potential of PFC designs based on different mathematical series for some current
optical applications such as optical filters, wavelength multipliers, and optical sensors.