Trace acetylene detection based on mid-infrared
laser absorption spectroscopy technology

doi:10.3969/j.issn.1007-5461.2021.05.009

Abstract

Abstract: Based on the combination of tunable diode mid-infrared laser absorption spectroscopy technology and long optical path multiple-reflection technology, the fast and real-time detection of trace acetylene in nmol/mol level is studied by using C2H2 gas absorption spectrum near 3025.7 nm in midinfrared region. The driving current of the interband cascade laser is modulated by the superimposition of the high frequency sine wave generated by DDS AD9958 and triangle wave signal, and then the stable driving of laser is realized through constant current circuit. HgCdTe photodetector is used to receive midinfrared laser, and target signal is extracted by integrated lock-in amplifier. A long optical path absorption cell is designed based on the combination of White multiple-reflection and plane reflection, and its measured optical path reaches 19.2 m, which further reduces the detection limit of C2H2. In laboratory, trace C2H2 gas sample is measured with the concentration ranging from 0 to 1000 nmol/mol. It shows that the linear error is less than ±1% F.S., and the detection limit is 0.29 nmol/mol, which indicates that the method has the advantages of high accuracy, no cross interference from background gas and convenient use.

Key words: spectroscopy, mid-infrared laser, multiple-reflection, C2H2 detection

CLC Number:

O433.4

LIU Lifu, FENG Yuxuan, CHEN Dong, YAN Mingyue, WU Qiang∗. Trace acetylene detection based on mid-infrared laser absorption spectroscopy technology[J]. Chinese Journal of Quantum Electronics, 2021, 38(5): 648-660.

References

[1]Li P, Xu J Z.Effect of different ASU process on ethane[J].Wisco Technology, 2006, 44(1):18-20
[2]李萍, 徐景章.不同空分流程对乙炔含量的影响[J].武钢技术, 2006, 44(1):18-20
[3] Feng B.Detecting Study Acetylene of Transformer Oil Used Infrared Laser Gas Sensor[D]. Chongqing: Chongqing University, 2012.
[4]冯波.红外激光气体传感器用于变压器油中乙炔检测研究[D]. 重庆: 重庆大学, 2012.
[5] Chen Y.Design of A Miniaturized Acetylene Gas Detection System Based on TDLAS Technology[D]. Changchun: Changchun Institute of Optics, Fine mechanics and Physics, Chinese Academy of Sciences, 2019.
[6]陈越.基于TDLAS技术的小型化乙炔气体检测系统的研制[D]. 长春: 中国科学院长春光学精密机械与物理研究所, 2019.
[7]Liu L X, Huan H T, Mandelis A, et al.Multiple dissolved gas analysis in transformer oil based on fourier transform infrared photoacoustic spectroscopy[J].Spectroscopy and Spectral Analysis, 2020, 40(3):684-687
[8]刘丽娴, 宦惠庭, , 等.多组分变压器油溶解气体的傅里叶变换红外光声光谱定量检测[J].光谱学与光谱分析, 2020, 40(3):684-687
[9] Huang H X.Study on Detection Characteristics of Trace Acetylene in Transformer Oil-dissolved Gas Based on Photoacoustic Spectroscopy[D]. Chongqing: Chongqing University, 2009.
[10]黄会贤.变压器油中微弱乙炔气体的光声光谱检测特性研究[D]. 重庆: 重庆大学, 2009.
[11]Ma Y F, Qiao S D, He Y, et al.Highly sensitive acetylene detection based on multi-pass retro-reflection-cavity-enhanced photoacoustic spectroscopy and a fiber amplified diode laser[J].Optics Express, 2019, 27(10):14163-14172
[12]Zhang B, Chen K, Chen YW, et al.High-sensitivity photoacoustic gas detector by employing multi-pass cell and fiber-optic microphone[J].Optics Express, 2020, 28(5):6618-6630
[13]Chen W G, Zhao L Z, Peng S Y, et al.Analysis of dissolved gas in transformer oil based on laser raman spectroscopy[J].Proceedings of the CSEE, 2014, 34(15):2485-2492
[14]陈伟根, 赵立志, 彭尚怡, 等.激光拉曼光谱应用于变压器油中溶解气体分析[J].中国电机工程学报, 2014, 34(15):2485-2492
[15]Zheng K Y, Zheng C T, He Q X, et al.Near-infrared acetylene sensor system using off-axis integrated-cavity output spectroscopy and two measurement schemes[J].Optics Express, 2018, 16(20):26205-26216
[18] Jiang L J.Research on CO, C2H2 Absorption Spectroscopy in Near Infrared and Measuring Instruments Miniaturization[D]. Taiyuan: Taiyuan University of science and technology, 2018.
[19]蒋利军.CO、C2H2的近红外吸收光谱及测量仪器的小型化研究[D]. 太原: 太原科技大学, 2018.
[20] Yu Y J.Study on Theory and Technology of Trace Gas Detection Based on Mid-Infrared Laser Absorption Spectroscopy[D]. Wuhan: Wuhan University, 2017.
[21]于亚军.基于中红外激光吸收光谱的痕量气体检测理论和技术研究[D]. 武汉: 武汉大学, 2017.
[22]Rothman L S, Gordon I E, Babikov Y, et al.The HITRAN2012 molecular spectroscopic database[J].Journal of Quantitative Spectroscopy & Radiative Transfer, 2013, 130(11):4-50
[23]Liu J Y, Sun B S, Zhang H F.Progress in research on on-line monitoring techniques for volatile organic compounds in ambient air[J].Chemical Industry and Engineering Progress, 2008, 27(5):648-653
[24]刘景允, 孙宝盛, 张海丰.空气中挥发性有机物在线监测技术研究进展[J].化工进展, 2008, 27(5):648-653
[25]He Y, Zhang Y J, Kan R F, et al.The development of acetylene on-line monitoring technology based on laser absorption spectrum[J].Spectroscopy and Spectral Analysis, 2008, 28(10):2228-2231
[26]何莹, 张玉钧, 阚瑞峰, 等.基于激光吸收光谱乙炔在线监测技术的研究[J].光谱学与光谱分析, 2008, 28(10):2228-2231
[27]Fu M J, Zhang Y B, Huang Y Q, et al.Progress of microbial monitoring(growth)based on TDLAS technology[J].Chinese Journal of Quantum Electronics, 2019, 36(2):129-136
[28]付美娟, 张逸彪, 黄瑜倩, 等.技术在微生物生长检测领域研究进展[J].量子电子学报, 2019, 36(2):129-136
[32]Xing K M, Yang K, Zhang L, et al.Simultaneous detection of CO and CO2 in cigarette mainstream smoke based on TDLAS technology[J].Chinese Journal of Quantum Electronics, 2017, 34(1):81-87
[33]邢昆明, 杨柯, 张龙, 等.基于技术同时检测卷烟主流烟气中的和[J].量子电子学报, 2017, 34(1):81-87
[36]Olafsen L J, Aifer E H, Vurgaftman I, et al.Near-room-temperature mid-infrared interband cascade laser[J].Applied Physics Letters, 1998, 72(19):2370-2372.

Trace acetylene detection based on mid-infrared laser absorption spectroscopy technology

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	MA Fengxiang , ZHAO Yue , LI Chenxi , AN Ran , ZHU Feng , HANG Chen , CHEN Ke . Analysis system of dissolved gas in oil based on optical fiber photoacoustic sensing [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 597-605.
[2]	CAO Dongmei , LI Yongfang . Investigation on localized surface plasmon resonance in bowtie gold dimer [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 606-613.
[3]	FEI Ye , SUN Zhongmou , TIAN Dongpeng , LIU Xiaoyuan , LIU Yuzhu , . Influence of fruit charcoal combustion on air composition based on laser⁃induced breakdown spectroscopy [J]. Chinese Journal of Quantum Electronics, 2023, 40(4): 436-446.
[4]	WANG Haiqing , , SHI Wei . Research progress of THz-ATR technology for detecting biomedical samples [J]. Chinese Journal of Quantum Electronics, 2023, 40(3): 319-332.
[5]	ZENG Ziwei , LI Hongguang, GUO Yufeng , LIAO Wentao. High-accuracy terahertz spectral identification method for concealed dangerous goods [J]. Chinese Journal of Quantum Electronics, 2023, 40(3): 340-348.
[6]	BAI Yanbing , , ZHANG Mengyuan , , ZHU Mengqi , , LI Xu , , YAN Jiayu , , ZHANG Cunlin , , ZUO Jian , . Terahertz kinetic study of α-lactose monohydrate [J]. Chinese Journal of Quantum Electronics, 2023, 40(3): 349-359.
[7]	GE Hongyi , , WANG Fei , , JIANG Yuying , , LI Li , , ZHANG Yuan , , JIA Keke , . Identification of wheat mold using terahertz images based on Broad Learning System [J]. Chinese Journal of Quantum Electronics, 2023, 40(3): 360-368.
[8]	ZHANG Ranran, YING Luna, ZHOU Weidong . Application of relevance vector machine combined with principal component analysis in quantitative analysis of LIBS [J]. Chinese Journal of Quantum Electronics, 2023, 40(3): 376-382.
[9]	ZHANG Mengsi , JU Wei , CHENG Zhiyou , REN Huidong. FTIR spectral wavenumber optimization for ethylene based on IRIV-SA [J]. Chinese Journal of Quantum Electronics, 2023, 40(3): 383-391.
[10]	WANG Kang , , LIU Yi , SONG Liwei ∗. Research progress in phase transition of vanadium dioxide ﬁlms driven by ultrafast optical ﬁeld [J]. Chinese Journal of Quantum Electronics, 2023, 40(2): 238-257.
[11]	YANG Jin , , WANG Yunfeng , , CHU Lingqiao , JIANG Huachao , SU Fuhai ∗. Investigation of ultrafast photocarrier dynamics in few-layer PtSe2 thin ﬁlms [J]. Chinese Journal of Quantum Electronics, 2023, 40(2): 282-292.
[12]	WANG Zeyu, CUI Qi, HE Xiaohu, LU Danhua, QIU Xuanbing, HE Qiusheng, LAI Yunzhong, LI Chuanliang∗. Computational and spectroscopic investigation of two lowest electronic states of I₊² [J]. Chinese Journal of Quantum Electronics, 2022, 39(4): 477-484.
[13]	XU Peng, JIA Ren, YAO Guanxin, QIN Zhengbo, ZHENG Xianfeng, YANG Xinyan, CUI Zhifeng, . Laser-induced breakdown spectroscopy of metal-element in mixed aqueous solutions by partial least-squares regression [J]. Chinese Journal of Quantum Electronics, 2022, 39(4): 485-493.
[14]	YU Wei, ZHOU Zhuoyan, SUN Zhongmou, ZHANG Xinglong, LIU Yuzhu, . Real-time detection of the genus Rosa L. using LIBS technology [J]. Chinese Journal of Quantum Electronics, 2022, 39(4): 494-501.
[15]	DING Bokun, SHAO Ligang, WANG Kunyang, CHEN Jiajin, WANG Guishi, LIU Kun, MEI Jiaoxu, TAN Tu, GAO Xiaoming, ∗. Research on real-time detection technology of dissolved gas in seawater based on off-axis integrating cavity [J]. Chinese Journal of Quantum Electronics, 2022, 39(4): 502-510.