Abstract
A simple hexagonal lattice photonic crystal fiber model with liquid-infiltrated core for different liquids: water, ethanol and benzene, has been proposed. In the proposed structure, three air hole rings are present in the cladding and three equal sized air holes are present in the core. Numerical investigation of the proposed fiber has been performed using full vector finite element method with anisotropic perfectly match layers, to show that the proposed simple structure exhibits high relative sensitivity, high power fraction, relatively high birefringence, low chromatic dispersion, low confinement loss, small effective area, and high nonlinear coefficient. All these properties have been numerically investigated at a wider wavelength regime 0.6–1.8 μm within mostly the IR region. Relative sensitivities of water, ethanol and benzene are obtained at 62.60%, 65.34% and 74.50%, respectively, and the nonlinear coefficients are 69.4 W−1 km−1 for water, 73.8 W−1 km−1 for ethanol and 95.4 W−1 km−1 for benzene, at 1.3 µm operating wavelength. The simple structure can be easily fabricated for practical use, and assessment of its multiple waveguide properties has justified its usage in real liquid detection.
Highlights
Possible applications in biosensing and chemical sensing have provoked its use in medical science and chemical industry, which have resulted in a large number of researchers taking a keen interest to increase sensitivity of the Photonic crystal fibers (PCFs) for different liquids, chemicals and gases
The proposed PCF has been designed for sensing analytes and the performance of the proposed structure is analyzed by considering different parameters including birefringence, relative sensitivity, chromatic dispersion, confinement loss, effective area, nonlinear coefficient and power fraction for ethanol, water and benzene
A simple hexagonal shape PCF with three liquid-infiltrated core holes and cladding air holes arranged in hexagonal geometry in three layers has been proposed for liquid sensing application in the lower optical wavelength
Summary
Photonic crystal fibers (PCFs) have recently gained prominence in research and have been implemented in sensing applications due to the special characteristics of these photonic fibers [1]. Numerous sensing application such as biosensing, gas sensing, chemical sensing and temperature sensing have already been proposed in [1,2,3,4,5]. Material for the PCF is often made from pure silica, whilst its cladding consists mostly of air holes that runs along the major fiber axis to provide a low refractive index region beyond the core. With respect to the design, PCFs can be designed for practical sensing application in environmental, biomedical and industry sectors
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