4-Channel Tunable Optical Demultiplexer Based on Nonlinearity Phenomenon in 2D Resonant Cavity Photonic Crystals

Reza Talebzadeh; Farhad Mehdizadeh; Ali Naseri

doi:10.1515/freq-2019-0082

Article

4-Channel Tunable Optical Demultiplexer Based on Nonlinearity Phenomenon in 2D Resonant Cavity Photonic Crystals

Reza Talebzadeh , Farhad Mehdizadeh and Ali Naseri

Published/Copyright: September 11, 2019

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From the journal Frequenz Volume 74 Issue 1-2

Abstract

In this paper, we propose a new structure based on photonic crystals to realise a demultiplexing operation for dense wavelength division multiplexing transmission systems. In this demultiplexer, the resonant cavities were responsible for selecting the wavelength. By imposing defect rods to these cavities, the modes could resonate at the desired frequencies. As we wanted to see the nonlinear effects, the material that was chosen for defect rods were doped glass. The refractive index of this glass in 1550 nm is 1.41. Increasing the input power causes variation in the refractive index of defect rods and as a result resonant condition of whole cavity alerts so a tenable demultiplexer can be investigated. Based on the results, the average pass bands of channels are near to 1.5 nm and the channel spacing is approximately 3.95 nm. The proposed demultiplexer acts in a near-complete transmission efficiency and the mean value of the crosstalk was −19 dB.

Keywords: nonlinearity; Kerr effect; refractive index; optical demultiplexer; photonic crystal

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Received: 2019-05-26

Published Online: 2019-09-11

Published in Print: 2020-01-28

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Articles in the same Issue

https://doi.org/10.1515/freq-2019-0082

Keywords for this article

nonlinearity; Kerr effect; refractive index; optical demultiplexer; photonic crystal