| 光谱学与光谱分析 |
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| A Review of Mixed Gas Detection System Based on Infrared Spectroscopic Technique |
| DANG Jing-min1, FU Li1, YAN Zi-hui2, ZHENG Chuan-tao1, CHANG Yu-chun1, CHEN Chen3*, WANG Yi-ding1* |
1. State Key Laboratory on Optoelectronics, College of Electronic Science and Engineering, Jilin University, Changchun 130012, China
2. Department of Automation, Tsinghua University, Beijing 100084, China
3. College of Instrumentation and Electrical Engineering, Jilin University, Changchun 130026, China |
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Abstract In order to provide the experiences and references to the researchers who are working on infrared(IR) mixed gas detection field. The proposed manuscript reviews two sections of the aforementioned field, including optical multiplexing structure and detection method. At present, the coherent light sources whose representative are quantum cascade laser (QCL) and interband cascade laser(ICL) become the mainstream light source in IR mixed gas detection, which replace the traditional non-coherent light source, such as IR radiation source and IR light emitting diode. In addition, the photon detector which has a super high detectivity and very short response time is gradually beyond thermal infrared detector, dominant in the field of infrared detector. The optical multiplexing structure is the key factor of IR mixed gas detection system, which consists of single light source multiplexing detection structure and multi light source multiplexing detection structure. Particularly, single light source multiplexing detection structure is advantages of small volume and high integration, which make it a plausible candidate for the portable mixed gas detection system; Meanwhile, multi light source multiplexing detection structure is embodiment of time division multiplex, frequency division multiplexing and wavelength division multiplexing, and become the leading structure of the mixed gas detection system because of its wider spectral range, higher spectral resolution, etc. The detection method applied to IR mixed gas detection includes non-dispersive infrared (NDIR) spectroscopy, wavelength and frequency-modulation spectroscopy, cavity-enhanced spectroscopy and photoacoustic spectroscopy, etc. The IR mixed gas detection system designed by researchers after recognizing the whole sections of the proposed system, which play a significant role in industrial and agricultural production, environmental monitoring, and life science, etc.
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Received: 2014-03-18
Accepted: 2014-08-12
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Corresponding Authors:
CHEN Chen, WANG Yi-ding
E-mail: cchen@jlu.edu.cn; wangyiding48@yahoo.com.cn
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[1] Tittel F K, Dong L, Lewicki R, et al. Conference on Lasers and Electro-Optics/Pacific Rim. Optical Society of America, 2011, C59.
[2] Cristescu S M, Persijn S T, te Lintel Hekkert S, et al. Applied Physics B, 2008, 92(3): 343.
[3] Gabrysch M, Corsi C, Pavone F S, et al. Applied Physics B, 1997, 65(1): 75.
[4] Pine A S. Journal of the Optical Society of America, 1974, 64(12): 1683.
[5] Smith R G, Geusic J E, Levinstein H J, et al. Applied Physics Letters, 1968, 12(9): 308.
[6] Fischer C, Sigrist M W. Mid-IR Difference Frequency Generation. Springer Berlin Heidelberg, 2003. 99.
[7] Petrov K P, Curl R F, Tittel F K. Applied Physics B, 1998, 66(5): 531.
[8] Capasso F. Optical Engineering, 2010, 49(11): 111102.
[9] Vodopyanov K L, Levi O, Kuo P S, et al. Optics Letters, 2004, 29(16): 1912.
[10] Hegenbarth R, Steinmann A, Sarkisov S, et al. Optics Letters, 2012, 37(17): 3513.
[11] Tan Q, Zhang W, Xue C, et al. Optics & Laser Technology, 2008, 40(5): 703.
[12] Enomoto T, Tanemura T, Yamashita S, et al. Multi-Gas Sensor by Infrared Spectra Meter. Springer Berlin Heidelberg, 2013. 611.
[13] Frish M B. Advanced Semiconduction Lasers and Their Applications. Optical Society of America, 1999. 32.
[14] Jimenez R, Herndon S, Shorter J H, et al. Integrated Optoelectronic Devices,2005, 5738: 319.
[15] Mukherjee A, Prasanna M, Lane M, et al. Applied Optics, 2008, 47(27): 4884.
[16] Danilova T N, Zhurtanov B E, Imenkov A N, et al. Semiconductors, 2005, 39(11): 1235.
[17] Hodgkinson J, Tatam R P. Measurement Science and Technology, 2013, 24(1): 012004.
[18] Ye W L, Zheng C T, Yu X, et al. Sensors and Actuators B: Chemical, 2011, 155(1): 37.
[19] Uehara K. Applied Physics B: Lasers and Optics, 1998, 67(4): 517.
[20] Reid J, Labrie D. Applied Physics B, 1981, 26(3): 203.
[21] Werle P, Slemr F. Applied Optics, 1991, 30(4): 430.
[22] SUN Yi, TAN Tu, GAO Xiao-ming(孙 义, 谈 图, 高晓明). Applied Optics(应用光学), 2008, 29(2): 257.
[23] Carlisle C B, Cooper D E, Preier H. Applied Optics, 1989, 28(13): 2567.
[24] Cai T, Wang G, Zhang W, et al. Measurement, 2012, 45(8): 2089.
[25] Griffiths A D, Houwing A F P. Applied Optics, 2005, 44(31): 6653.
[26] OKeefe A, Deacon D A G. Review of Scientific Instruments, 1988, 59(12): 2544.
[27] Paldus B A, Kachanov A A. Canadian Journal of Physics, 2005, 83(10): 975.
[28] Adler F, Thorpe M J, Cossel K C, et al. Annual Review of Analytical Chemistry, 2010, 3: 175.
[29] Miklós A, Hess P, Bozóki Z. Review of Scientific Instruments, 2001, 72(4): 1937.
[30] Kosterev A A, Serebryakov D V, Malinovsky A L, et al. Review of Scientific Instruments, 2005, 76(4): 043105.
[31] Pushkarsky M B, Webber M E, Patel C K N. Applied Physics B, 2003, 77(4): 381.
[32] Schmohl A, Miklós A, Hess P. Applied Optics, 2002, 41(9): 1815.
[33] Saarela J, Sorvajrvi T, Laurila T, et al. Optics Express, 2011, 19(104): A725.
[34] Kosterev A A, Bakhirkin Y A, Curl R F, et al. Optics Letters, 2002, 27(21): 1902.
[35] Koskinen V, Fonsen J, Roth K, et al. Applied Physics B, 2007, 86(3): 451.
[36] Shorter J H, Nelson D D, McManus J B, et al. Sensors Journal, Institute of Electrical and Electronics Engineers, 2010, 10(1): 76.
[37] Todd M W, Provencal R A, Owano T G, et al. Applied Physics B, 2002, 75(2-3): 367.
[38] Schilt S, Thévenaz L, Niklès M, et al. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2004, 60(14): 3259. |
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