Design and Sensitivity Improvement of Microstructured-Core Photonic Crystal Fiber Based Sensor for Methane and Hydrogen Fluoride Detection

This paper describes a gas detection sensor that is based on a microstructured-core photonic crystal fiber (PCF). The finite element method (FEM) is used to analyze the quantitative dependence of guiding properties on geometrical parameters along wavelength. The result shows that the structure provides high relativity sensitivity with minimal confinement loss for detecting various gases such as methane (CH4) and hydrogen fluoride (HF) because the proposedPCF introduces microstructured-core. According to the results of this simulation, an absorptive line of CH4/HF gases could have a maximum relative sensitivity of about 44.47% at wavelength of 1.33 mu m with the optimal design of the PCF. The proposed sensor has a confinement loss of around 1.83 x 10(-8) dB/m, that is very low and suitable for use as a gas sensor. Furthermore, numerical aperture (NA), V-parameter, Marcuse spot size (MSS), and beam divergence (BD) are extensively investigated in the wavelength range of 1.3 to 2.2 mu m. These findings should aid in the development of a high-efficiency PCF for gas sensing and monitoring air pollution.

Automated summary

This paper presents a gas detection sensor based on microstructured-core photonic crystal fiber, and analyzes the quantitative dependence of its guiding properties on geometrical parameters at different wavelengths. The sensor shows high sensitivity and minimal confinement loss, making it suitable for detecting gases such as methane and hydrogen fluoride.