Natural logarithm wavelength modulation spectroscopy

Shaomin Li; Liqun Sun

doi:10.3788/COL202119.031201

[1] C. Ruan, D. Kong, J. Dai, K. Chen, S. Guo, X. Wu. High-resolution frequency-domain spectroscopy for water vapor with coherent and continuous terahertz wave. Chin. Opt. Lett., 17, 073001(2019).

[2] J. Zou, F. Wang. Simultaneous measurement of SO2 and NO2 concentration using an optical fiber-based LP-DOAS system. Chin. Opt. Lett., 18, 021201(2020).

[3] J. Hodgkinson, R. P. Tatam. Optical gas sensing: a review. Meas. Sci. Technol., 24, 012004(2013).

[4] J. Li, B. Yu, W. Zhao, W. Chen. A review of signal enhancement and noise reduction techniques for tunable diode laser absorption spectroscopy. Appl. Spectrosc. Rev., 49, 666(2014).

[5] K. K. Schwarm, C. L. Strand, V. A. Miller, R. M. Spearrin. Calibration-free breath acetone sensor with interference correction based on wavelength modulation spectroscopy near 8.2 µm. Appl. Phys. B, 126, 9(2020).

[6] J. Xia, F. Zhu, A. A. Kolomenskii, J. Bounds, S. Zhang, M. Amani, L. J. Fernyhough, H. A. Schuessler. Sensitive acetone detection with a mid-IR interband cascade laser and wavelength modulation spectroscopy. OSA Continuum, 2, 640(2019).

[7] G. B. Rieker, J. B. Jeffries, R. K. Hanson, T. Mathur, M. R. Gruber, C. D. Carter. Diode laser-based detection of combustor instabilities with application to a scramjet engine. Proc. Combustion Institute, 32, 831(2009).

[8] R. K. Hanson, P. A. Kuntz, C. H. Kruger. High-resolution spectroscopy of combustion gases using a tunable ir diode laser. Appl. Opt., 16, 2045(1977).

[9] X. Chao, J. B. Jeffries, R. K. Hanson. Real-time, in situ, continuous monitoring of CO in a pulverized-coal-fired power plant with a 2.3 µm laser absorption sensor. Appl. Phys. B, 110, 359(2013).

[10] H. Li, A. Farooq, J. B. Jeffries, R. K. Hanson. Near-infrared diode laser absorption sensor for rapid measurements of temperature and water vapor in a shock tube. Appl. Phys. B, 89, 407(2007).

[11] C. Li, Y. Wu, X. Qiu, J. Wei, L. Deng. Pressure-dependent detection of carbon monoxide employing wavelength modulation spectroscopy using a Herriott-type cell. Appl. Spectrosc., 71, 809(2017).

[12] C. Li, L. Shao, L. Jiang, X. Qiu, J. Wei, W. Ma. Simultaneous measurements of CO and CO2 employing wavelength modulation spectroscopy using a signal averaging technique at 1.578 µm. Appl. Spectrosc., 72, 1380(2018).

[13] J. Mikołajczyk, J. Wojtas, Z. Bielecki, T. Stacewicz, D. Szabra, P. Magryta, A. Prokopiuk, A. Tkacz, M. Panek. System of optoelectronic sensors for breath analysis. Metrol. Meas. Syst., 23, 481(2016).

[14] G. B. Rieker, J. B. Jeffries, R. K. Hanson. Calibration-free wavelength-modulation spectroscopy for measurements of gas temperature and concentration in harsh environments. Appl. Opt., 48, 5546(2009).

[15] A. J. McGettrick, K. Duffin, W. Johnstone, G. Stewart, D. G. Moodie. Tunable diode laser spectroscopy with wavelength modulation: a phasor decomposition method for calibration-free measurements of gas concentration and pressure. J. Lightwave Technol., 26, 432(2008).

[16] W. Ding, L. Sun, L. Yi, E. Zhang. ‘Baseline-offset’ scheme for a methane remote sensor based on wavelength modulation spectroscopy. Meas. Sci. Technol., 27, 085202(2016).

[17] G. B. Rieker, H. Li, X. Liu, J. B. Jeffries, R. K. Hanson, M. G. Allen, S. D. Wehe, P. A. Mulhall, H. S. Kindle. A diode laser sensor for rapid, sensitive measurements of gas temperature and water vapour concentration at high temperatures and pressures. Meas. Sci. Technol., 18, 1195(2007).

[18] G. Zhao, W. Tan, J. Hou, X. Qiu, W. Ma, Z. Li, L. Dong, L. Zhang, W. Yin, L. Xiao, O. Axner, S. Jia. Calibration-free wavelength-modulation spectroscopy based on a swiftly determined wavelength-modulation frequency response function of a DFB laser. Opt. Express, 24, 1723(2016).

[19] I. E. Gordon, L. S. Rothman, C. Hill, R. V. Kochanov, Y. Tan, P. F. Bernath, M. Birk, V. Boudon, A. Campargue, K. V. Chance, B. J. Drouin, J.-M. Flaud, R. R. Gamache, J. T. Hodges, D. Jacquemart, V. I. Perevalov, A. Perrin, K. P. Shine, M.-A. H. Smith, J. Tennyson, G. C. Toon, H. Tran, V. G. Tyuterev, A. Barbe, A. G. Császár, V. M. Devi, T. Furtenbacher, J. J. Harrison, J.-M. Hartmann, A. Jolly, T. J. Johnson, T. Karman, I. Kleiner, A. A. Kyuberis, J. Loos, O. M. Lyulin, S. T. Massie, S. N. Mikhailenko, N. Moazzen-Ahmadi, H. S. P. Müller, O. V. Naumenko, A. V. Nikitin, O. L. Polyansky, M. Rey, M. Rotger, S. W. Sharpe, K. Sung, E. Starikova, S. A. Tashkun, J. V. Auwera, G. Wagner, J. Wilzewski, P. Wcisło, S. Yu, E. J. Zak. The HITRAN2016 molecular spectroscopic database. J. Quantum Spectrosc. Radiat. Transfer, 203, 3(2017).

Data from CrossRef

微信扫一扫：分享

微信扫一扫：分享