Scientific Reports (Dec 2024)
Numerical optimization of anti resonant hollow core fiber for high sensitivity methane detection
Abstract
Abstract This study presents an innovative methane gas sensor design based on anti-resonant hollow-core fiber (AR-HCF) technology, optimized for high-precision detection at 3.3 $$\:\:{\upmu\:}\text{m}$$ . Our numerical analysis explores the geometric optimization of the AR-HCF’s structural parameters, incorporating real-world component specifications. The proposed design features a 65 $$\:\:{\upmu\:}\text{m}$$ diameter hollow core surrounded by seven silica rings. We achieved significant improvements in confinement loss and optical power distribution through progressive structural modifications. The optimized structure demonstrated a confinement loss of $$\:1.85\times\:{10}^{-4}\:\text{d}\text{B}/\text{m}$$ and over 95% optical power confinement in the hollow core. Our model predicts a relative sensitivity of $$\:0.1745\:\text{A}\text{U}/\text{p}\text{p}\text{m}$$ , a response time of 5.4 s, and a theoretical detection threshold of 2.24 ppm. The limit of detection (LoD) was estimated to be 3.8 ppbv, and the normalized noise equivalent absorption (NNEA) coefficient was $$\:1.22\times\:{10}^{-10}\:\text{W} \; {\text{c}\text{m}}^{-1} \; {\text{H}\text{z}}^{-1/2}$$ . The sensor response exhibited excellent linearity over its operating range, with an R2 value of 0.9917 in the critical concentration range. These findings highlight the potential of our AR-HCF-based methane sensor design for real-time gas monitoring applications.
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