Design of Barium Crown Glass Based Hollow Dual Core Hexagon Pcf Filled With Selective Liquid
International Journal of Electronics and Communication Engineering |
© 2020 by SSRG - IJECE Journal |
Volume 7 Issue 3 |
Year of Publication : 2020 |
Authors : Divakar Kumar, Neha Kumari |
How to Cite?
Divakar Kumar, Neha Kumari, "Design of Barium Crown Glass Based Hollow Dual Core Hexagon Pcf Filled With Selective Liquid," SSRG International Journal of Electronics and Communication Engineering, vol. 7, no. 3, pp. 35-41, 2020. Crossref, https://doi.org/10.14445/23488549/IJECE-V7I3P106
Abstract:
Two different dual hollow-core PCF structures are proposed, designed, and analyzed using Rsoft FEMSIM software. The first structure consists of a circular air hole, and the second structure consists of a square air hole. Silica glass is replaced by barium crown glass. The CS2 is filled in the core, and the refractive index of CS2 is 1.5956. Both square-shaped and circular-shaped hexagon lattice dual-core PCF made up of the same material. Low confinement loss, high birefringence as 1.093 x 10-3for circular air holes and 8.49 x 10-3 for square air holes, Negative dispersion, effective refractive index, normalized frequency, effective area, and nonlinear coefficient are surveyed by varying the diameter of the air hole of cladding. Compare the parameters of both the designed PCF.
Keywords:
PCF, HCPCF, Photonic Band Gap, SPSM, QoS.
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