Numerical analysis of gas diffusion in drilled Hollow-Core Photonic Crystal fibres

Abstract: Hollow-Core Photonic Crystal Fibres (HC-PCFs) have emerged as an area of interest for fibre-optic based distributed gas sensing. In order to allow the gas to enter the hollow core of the fibre, various techniques such as lateral drilled side holes have been investigated in the literature. However, it is essential to understand the mechanisms of gas flow in HC-PCFs with drilled side holes in order to determine the optimum design parameters of the sensor such as the size and spacing of drilled side holes. This s… Show more

“… in which h is the channel depth, C ( x , t ) is the target gas concentration inside the channel, D is the target gas diffusivity in the background atmosphere, C a is the surface density of the adsorption sites, and b is a constant related to the nature of the target gas and the channel coating. The solutions of eq have provided valid predictions of the diffusion rates in capillaries of different geometries for various purposes. ,, In all experiments, the target molecule concentration is below 0.04 mol/m 3 in the test chamber and is at much lower levels inside the microchannel. Therefore, bC ( x , t ) is much smaller than 1.0. ,, Hence, eq takes the following approximate form: Adsorbate-dependent parameters in eq are D , b , and C a .…”

“…The solutions of eq 1 have provided valid predictions of the diffusion rates in capillaries of different geometries for various purposes. 52,54,55 In all experiments, the target molecule concentration is below 0.04 mol/m 3 in the test chamber and is at much lower levels inside the microchannel. Therefore, bC(x,t) is much smaller than 1.0.…”

Quantitative Assessment of Vapor Molecule Adsorption to Solid Surfaces by Flow Rate Monitoring in Microfluidic Channels

“… in which h is the channel depth, C ( x , t ) is the target gas concentration inside the channel, D is the target gas diffusivity in the background atmosphere, C a is the surface density of the adsorption sites, and b is a constant related to the nature of the target gas and the channel coating. The solutions of eq have provided valid predictions of the diffusion rates in capillaries of different geometries for various purposes. ,, In all experiments, the target molecule concentration is below 0.04 mol/m 3 in the test chamber and is at much lower levels inside the microchannel. Therefore, bC ( x , t ) is much smaller than 1.0. ,, Hence, eq takes the following approximate form: Adsorbate-dependent parameters in eq are D , b , and C a .…”

“…The solutions of eq 1 have provided valid predictions of the diffusion rates in capillaries of different geometries for various purposes. 52,54,55 In all experiments, the target molecule concentration is below 0.04 mol/m 3 in the test chamber and is at much lower levels inside the microchannel. Therefore, bC(x,t) is much smaller than 1.0.…”

Quantitative Assessment of Vapor Molecule Adsorption to Solid Surfaces by Flow Rate Monitoring in Microfluidic Channels

All-circular hole microstructured fiber with ultra-high birefringence and reduced confinement loss

Experimental and numerical analysis of gas flow in nodeless antiresonant hollow-core fibers for optimization of laser gas spectroscopy sensors