[1] PIKHART H, BOBAK M, KRIZ B, et al. Outdoor air concentrations of nitrogen dioxide and sulfur dioxide and prevalence of wheezing in school children[J]. Epidemiology, 2000, 11(2): 153-160.
[2] KORTH H G. The pathobiochemistry of nitrogen dioxide[J]. Biological Chemistry, 2002, 383(3-4): 389-399.
[3] SACHIN D G, R J VANDER A, BEIG G, et al. Satellite derived trends in NO2 over the major global hotspot regions during the past decade and their inter-comparison[J]. Environmental Pollution, 2009, 157(6): 1873-1878.
[4] TIAN G, MOOSMLLER H, ARNOTT W P. Influence of photolysis on multispectralphotoacoustic measurement of nitrogen dioxide concentration[J]. Journal of the Air & Waste Management Association, 2013, 63(9): 1091-1097.
[5] ORPHAL J, DREHER S, VOIGT S, et al. The near-infrared bands of NO2 observed by high-resolution Fourier-transform spectroscopy[J]. Journal of Chemical Physics, 1998, 109(23): 10217-10211.
[6] LIN Wei-hao, GAO Zhi-hui, YANG Yong, et al. NO2 detection based on laser spectrum differential method[J]. Laser Technology, 2014, 38(6): 835-838.
[7] LIANG Mei, PENG Guan, ZHENG Kong. Remotesensing of atmospheric NO2 by employing the continuous-wave differential absorption lidar technique[J]. Optics Express, 2017, 25(20): A953.
[8] KOLSCH H J, RAIROUX P, WOLF J P, et al. Simultaneous NO and NO2 DIAL measurement using BBO crystals[J]. Applied Optics, 1989, 28(11): 2052-2056.
[9] TORIUMI R, TAI H, TAKEUCHI N. Tunable solid-state blue laser differential absorption lidar system for NO2 monitoring[J]. Optical Engineering, 1996, 35(8): 2371-2375.
[10] CELARIER E A, BRINKSMA E J, GLEASON J F, et al. Validation of ozone monitoring instrument nitrogen dioxide columns[J]. Journal of Geophysical Research, 2008, 113(D15): D15S15.
[11] LIU Zun-yang, BIAN Jin-tian, SHAO Li, et al. Progress of mid infrared laser technology[J]. Laser and Infrared, 2013, 43(8): 853-858.
[12] YI Hong-ming, LIU Kun, CHEN Wei-dong, et al. Application of a broadband blue laser diode to trace NO2 detection using off-beam quartz-enhanced photoacoustic spectroscopy[J]. Optics Letters, 2011, 36(4): 481-483.
[13] CUI Hou-xin, DU Zhen-hui, CHEN Wen-liang, et al. Effect of temperature on the absorption cross-section of NO2 in 410~440 nm Wavelength[J]. Journal of Tianjin University, 2008, 41(10): 1162-1166.
[14] SA Ri-na, BU Ling-bing, WANG Qin, et al. Spectral characteristics of polluted gases and their detection by mid-infrared differential absorption lidar[J]. Optik, 2017, 149: 113-124.
[15] XU Ling, BU Ling-bing, CAI Hao-ze, et al. Wavelength selection and detection capability simulation of the mid-infrared DIAL for NO2 detecion[J]. Laser and Infrared, 2018, 47(10): 77-84.
[17] CHEN Ya-feng, WANG Xiao-bin, LIU Qiu-wu, et al. Mobile SO2 Differential absorption lidar system[J]. Acta Photonica Sinica, 2017, 46(7): 0701004.
[18] ZHU Xiang-fei, LIN Zhao-xiang, LIU Lin-mei, et al. Influence of temperature and pressure on absorption spectrum of around 1.6 μm for differential absorption lidar[J]. Acta Physica Sinica, 2014, 63(17): 153-159.
[19] CARON J, DURAND Y, BEZY J L, et al. Performance modeling for A-SCOPE: a space-borne lidar measuring atmospheric CO2[C]. SPIE, 2009.
[20] CARON J, DURAND Y. Operating wavelengths optimization for a spaceborne lidar measuring atmospheric CO2[J]. Applied Optics, 2009, 48(28): 5413-5422.
[21] LIU Hao. Research on differential absorption lidar for CO2 sensing[D]. Shanghai: Shanghai Institute of Technical Physics, 2015.