Influence of Temperature on the Chromatic Dispersion of Photonic Crystal Fiber by Infiltrating the Air Holes with Water
-
Mohammed Debbal
,
Mouweffeq Bouregaa
Abstract
This paper describes study of photonic crystal fiber (PCF) in order to study the influence of temperature on the chromatic dispersion; these types of fibers are based on commercial structures, but air holes will be infiltrated with water. Using finite domain-beam propagation method, it is shown that the zero dispersion wavelength can be shifted from 1.058753 to 1.271767 µm, a shift of 213 nm. At 50 °C, a shift of 169 nm.
As a result, we reveal that the proposed PCF can successfully compensate for the chromatic dispersion by the influence of temperature. Furthermore, the design model and methodology can be applied to design other dispersion-based devices, such as dispersion-flattened fibers and dispersion-shifted fibers, or can be used also as a sensor of temperature.
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© 2019 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Frontmatter
- Devices
- Dual-Buffer-Based Optical Datacenter Switch Design
- Fibers
- Influence of Temperature on the Chromatic Dispersion of Photonic Crystal Fiber by Infiltrating the Air Holes with Water
- Performance Analysis of 80 GHz-Millimeter Wave Radio over Dispersive Fiber
- Lasers
- Design and Analysis of Static Characteristics of VCSEL at 1160 nm for Optical Interconnects
- Measurements
- Measurements of the dispersion, the dispersion slope and nonlinear coefficients of photonic crystal fibers based on degenerate four-wave mixing (FWM)
- Networks
- Research on CLIB Routing and Spectrum Allocation Algorithm in Elastic Optical Networks
- Performance Evaluation of Hybrid Optical Amplifier for Ultra Dense Wavelength Division Multiplexed Optical Network at Narrow Channel Spacing
- Systems
- FPGA Implementation of a Novel Construction of Optical Zero-Correlation Zone Codes for OCDMA Systems
- Work on the Evaluation Parameters of Serial and Parallel Relay-Assisted FSO System
- Performance Analysis of a Non-Hermitian OFDM Optical DQPSK FSO Link over Atmospheric Turbulent Channel
- Hybrid Optical Amplifier for Flat Gain in Super Dense Wavelength Division Multiplexed (SDWDM) System
- An All-Optical System for Implementing Integrated Hadamard-Pauli Quantum Logic
- Phonon Polariton Dispersion in Metal-Doped Nanocomposite Superlattice System
- Radio over Fibre Transport of Alamouti-coded MIMO Signals with Self-Recovery Capability
- DP-QPSK Technique for Ultra-high Bit-rate DWDM FSO System
- Design and Analysis of Alphabetical Slots of Patch Antenna for Mobile Optical Communication at 60 GHz
- Bidirectional MDRZ Downstream and NRZ OOK Upstream SS-WDM RoFSO Communication System
Artikel in diesem Heft
- Frontmatter
- Devices
- Dual-Buffer-Based Optical Datacenter Switch Design
- Fibers
- Influence of Temperature on the Chromatic Dispersion of Photonic Crystal Fiber by Infiltrating the Air Holes with Water
- Performance Analysis of 80 GHz-Millimeter Wave Radio over Dispersive Fiber
- Lasers
- Design and Analysis of Static Characteristics of VCSEL at 1160 nm for Optical Interconnects
- Measurements
- Measurements of the dispersion, the dispersion slope and nonlinear coefficients of photonic crystal fibers based on degenerate four-wave mixing (FWM)
- Networks
- Research on CLIB Routing and Spectrum Allocation Algorithm in Elastic Optical Networks
- Performance Evaluation of Hybrid Optical Amplifier for Ultra Dense Wavelength Division Multiplexed Optical Network at Narrow Channel Spacing
- Systems
- FPGA Implementation of a Novel Construction of Optical Zero-Correlation Zone Codes for OCDMA Systems
- Work on the Evaluation Parameters of Serial and Parallel Relay-Assisted FSO System
- Performance Analysis of a Non-Hermitian OFDM Optical DQPSK FSO Link over Atmospheric Turbulent Channel
- Hybrid Optical Amplifier for Flat Gain in Super Dense Wavelength Division Multiplexed (SDWDM) System
- An All-Optical System for Implementing Integrated Hadamard-Pauli Quantum Logic
- Phonon Polariton Dispersion in Metal-Doped Nanocomposite Superlattice System
- Radio over Fibre Transport of Alamouti-coded MIMO Signals with Self-Recovery Capability
- DP-QPSK Technique for Ultra-high Bit-rate DWDM FSO System
- Design and Analysis of Alphabetical Slots of Patch Antenna for Mobile Optical Communication at 60 GHz
- Bidirectional MDRZ Downstream and NRZ OOK Upstream SS-WDM RoFSO Communication System
