Comparative study of fundamental properties of honey comb photonic crystal fiber at 1.55µm wavelength

Mishra, Sabyashachi; Singh, Vinod Kumar

doi:10.1590/s2179-10742011000200005

Cited by 6 publications

(4 citation statements)

References 25 publications

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“…The PCF is having so many unique properties such as high birefringence [1], [6], high nonlinearity [2], [4], wideband dispersion flattened characteristics [1]- [4], [6]- [8], endlessly single mode guiding [1], [2], [6] so that they are widely used in fiber sensors application [1] and fiber lasers as well as supercontinuum generation [10], nonlinear optics [2], [4], telecommunications, soliton [2], medical instrumentations [9] and many more application which are not realizable by conventional optical fiber.…”

Section: Advantage and Transmission Window Of Pcfsmentioning

confidence: 99%

“…However, many previous designs are all based on triangular PCFs [1], [3], [5] (see Figure 1), ultra-flattened dispersion properties of square-lattice PCFs [6] (see Figure 2) and a few reports on ultra-flattened dispersion properties of honeycomb PCFs [8], [9], [11]. A few designs were proposed on honeycomb PCF.…”

Section: Introductionmentioning

confidence: 99%

“…These designs do not have better dispersion as compare to other design so it is very necessary to investigate ultra-flattened dispersion in honeycomb PCFs. Now days, exploiting multiple design parameters such as diameter of air holes, shape of the holes (like circular, square, elliptical) and pitch difference, using different kinds of available materials like silica [1]- [5], [7]- [9], As 2 Se 3 , borosilicate crown glass [10], [12] etc., the number of air hole rings and the spacing between these holes facilitates development of PCFs with improved properties.…”

Section: Introductionmentioning

confidence: 99%

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Design of a New Honeycomb PCF for Ultraflatten Dispersion over Wideband Communication System

Bapna¹,

Pandey²

2016

IJCA

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A new kind of honeycomb photonic crystal fiber structure with triangular lattice is proposed. For the proposed design three different air-hole diameters in cladding region is used. To calculate dispersion, 2-D finite difference frequency domain method with the Transparent Boundary conditions (TBC) absorbing boundary conditions is used. Through the numerical simulation and optimizing the geometrical parameters like changing the diameter of air holes (d) for photonic crystal fibers in triangular lattice structure, it has been demonstrated that it is possible to obtain ultra flatten dispersion over a wide wavelength range which lies in second and third telecom window. The ultra flatten dispersion 0±0.13 is obtained in the wavelength range 1.4 to 1.71μm. The proposed structure is designed using seven ring in which circular air holes are used. The best choice of material for the designing purpose is silica with refractive index 1.458.

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Section: Advantage and Transmission Window Of Pcfsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Design of a New Honeycomb PCF for Ultraflatten Dispersion over Wideband Communication System

Bapna¹,

Pandey²

2016

IJCA

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“…The stop-band value depends primarily on three factors [19][20][21][22]: the refractive index contrast between the dielectric components (solid and air usually), the lattice constant (the spacing between the spheres), and the filling factor (volume of the colloids related to the volume of surrounding media). In addition, one of the most challenging applications consists in fabricating photonic crystals with 3D band gap around 1.55 m representing the wavelength used in optical fibers [23].…”

Section: Photonic Crystalsmentioning

confidence: 99%

Optical Properties of the Self-Assembling Polymeric Colloidal Systems

Mocanu

Rusen

Diacon

2013

International Journal of Polymer Science

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In the last decade, optical materials have gained much interest due to the high number of possible applications involving path or intensity control and filtering of light. The continuous emerging technology in the field of electrooptical devices or medical applications allowed the development of new innovative cost effective processes to obtain optical materials suited for future applications such as hybrid/polymeric solar cells, lasers, polymeric optical fibers, and chemo- and biosensing devices. Considering the above, the aim of this review is to present recent studies in the field of photonic crystals involving the use of polymeric materials.

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