[1] Li H L, Li F C, Gao S et al. The measurement uncertainty analysis and evaluation of the CO2 detection system based on TDLAS[J]. Laser Journal, 38, 20-23(2017).
[2] Wang Z S. A gas detection system based on infrared absorption spectrum[P].
[3] Ma S, Wu T, Sun C L et al. Real-time exhaled CO2 gas measurement using a mid-infrared hollow waveguide fiber[J]. Acta Optica Sinica, 40, 1130001(2020).
[4] Herriott D R, Schulte H J. Folded optical delay lines[J]. Applied Optics, 4, 883-889(1965).
[5] Tuzson B, Mangold M, Looser H et al. Compact multipass optical cell for laser spectroscopy[J]. Optics Letters, 38, 257-259(2013).
[6] Zhang M, Zhang B, Chen K et al. Miniaturized multi-pass cell based photoacoustic gas sensor for parts-per-billion level acetylene detection[J]. Sensors and Actuators A: Physical, 308, 112013(2020).
[7] Blake T A, Kelly J F, Stewart T L et al. Absorption spectroscopy in hollow-glass waveguides using infrared diode lasers[J]. Proceedings of SPIE, 4817, 216-232(2002).
[8] Li Z L, Wang Z, Yang F et al. Mid-infrared fiber-optic photothermal interferometry[J]. Optics Letters, 42, 3718-3721(2017).
[9] Hoo Y L, Jin W, Ho H L et al. Gas diffusion measurement using hollow-core photonic bandgap fiber[J]. Sensors and Actuators B: Chemical, 105, 183-186(2005).
[10] Jin W, Cao Y, Yang F et al. Ultra-sensitive all-fibre photothermal spectroscopy with large dynamic range[J]. Nature Communications, 6, 6767(2015).
[11] Cui J H, Ding H, Li X L et al. Acetylene sensing system using hollow-core photonic crystal fiber as gas cell[J]. Acta Optica Sinica, 30, 2262-2266(2010).
[12] Belardi W. Design and properties of hollow antiresonant fibers for the visible and near infrared spectral range[J]. Journal of Lightwave Technology, 33, 4497-4503(2015).
[13] Jiang S L, Jin W, Chen F F et al. Carbon dioxide detection with high sensitivity based on photo-thermal spectroscopy in hollow-core optical fiber[J]. Acta Optica Sinica, 41, 1306004(2021).
[14] Zhao Y, Qi Y, Ho H L et al. Photoacoustic Brillouin spectroscopy of gas-filled anti-resonant hollow-core optical fibers[J]. Optica, 8, 532-538(2021).
[15] Jin W, Xu Y Z, Demokan M S et al. Investigation of interferometric noise in fiber-optic gas sensors with use of wavelength modulation spectroscopy[J]. Applied Optics, 36, 7239-7246(1997).
[16] Xin F X. Study on monitoring technology of atmospheric carbon dioxide concentration based on TDLAS[D], 20-30(2014).
[17] Wang M L, Gao S F, Wang Y Y et al. UV guiding hollow-core antiresonant fiber[J]. Chinese Journal of Lasers, 47, 0806002(2020).
[18] Litchinitser N M, Abeeluck A K, Headley C et al. Antiresonant reflecting photonic crystal optical waveguides[J]. Optics Letters, 27, 1592-1594(2002).
[19] Liu Z L. Methane monitoring system based on TDLAS[D](2013).
[20] Yu F, Wu D K, Wang Y Z et al. Delivery of CW laser power up to 300 watts at 1080 nm by an uncooled low-loss anti-resonant hollow-core fiber[J]. Optics Express, 29, 1492-1501(2020).
[21] Lin Y C, Jin W, Yang F et al. Performance optimization of hollow-core fiber photothermal gas sensors[J]. Optics Letters, 42, 4712-4715(2017).
[22] Liu F, Bao H H, Ho H L et al. Multicomponent trace gas detection with hollow-core fiber photothermal interferometry and time-division multiplexing[J]. Optics Express, 29, 43445-43453(2021).