Abstract
AbstractIn absorption spectroscopy, analysis of multicomponent gas mixtures becomes challenging when absorption features overlap (blended spectra). Here we propose a gas sensor which can accurately identify the species and retrieve the concentrations of components in a gaseous mixture in a broad spectrum. The sensor integrates a mid-infrared dual-frequency comb laser source for spectrum acquisition and a deep learning algorithm for spectral analysis. The sensor was tested on gas phase mixtures of methane, acetone and water vapor. A prototype sensor was assessed in realistic scenarios in real time. We also systematically analyzed and presented explicit visualizations to explain the underlying working mechanism of the algorithms.
Publisher
Springer Science and Business Media LLC
Reference52 articles.
1. Hundt, P. M. et al. Multi-species trace gas sensing with dual-wavelength QCLs. Appl. Phys. B 124, 1–9 (2018).
2. Sigrist, M. W. et al. Infrared laser-based sensing in medical applications. Quantum Sens. Nanophotonic Devices VII. SPIE 7608, 64–72 (2010).
3. Zhang, L. et al. A novel compact intrinsic safety full range Methane microprobe sensor using “trans-world” processing method based on near-infrared spectroscopy. Sens. Actuators B Chem. 334, 129680 (2021).
4. Xia, J., Zhu, F., Zhang, S., Kolomenskii, A. & Schuessler, H. A ppb level sensitive sensor for atmospheric methane detection. Infrared Phys. Techn. 86, 194–201 (2017).
5. Xia, J. et al. Probing greenhouse gases in turbulent atmosphere by long-range open-path wavelength modulation spectroscopy. Opt. Lasers Eng. 117, 21–28 (2019).