[1] |
CAO N W, XIE Y H, ZHU C X, et al. SO2-O3-aerosol simultaneous measurements by multi-wavelength differential absorption lidar[J]. Optical Technique, 2015, 41(4):289-295(in Chinese). |
[2] |
WANG W, DU X Q. To explore two methods for deter-mination of sulfur dioxide in air[J]. Low Carbon World, 2017(3):9-10(in Ch-inese). |
[3] |
YANG Ch P, HE Zh J, YANG G L, et al. Study on the optical performance of cell for the detection of sulfur dioxide in air[J]. Optical Technique, 2003, 29(1): 39-41(in Chinese). |
[4] |
LIN Q Y. Influencing factors of formaldehyde buffer solution absorption-pararosaniline spectroph-otometric determination of sulfur dioxide in air[J]. Fujian Construction Science & Technology, 2018(6): 43-44(in Chinese). |
[5] |
WANG Y Q. Determination of sulfur dioxide in ambient air-verification report of formaldehyde absorption spectrophotometry with rosaniline[J]. Jiangxi Chemical Industry, 2018(2):202-204(in Chinese). |
[6] |
WU Ch, YANG Zh H, RONG W F, et al. Determination of sulfur dioxide in workplace air by solid adsorption tube samplingion chromato-graphy[J]. China Occupational Medicine, 2018, 45(1):95-98(in Chinese). |
[7] |
LIN Y F. Simultaneous determination of sulfur dioxide and nitrogen oxides in ambient air by ion chromatography[J]. Environment and Development, 2017, 29(3):205-206(in Chinese). |
[8] |
CAI L, QIN J. Analysis and research on standard gas iodimetry of sulfur dioxide[J]. Technical Supervision of Petroleum Industry, 2018, 34(1): 45-47(in Chinese). |
[9] |
HU K X, YAO L, YANG D D. Influencing factors of determination of sulfur dioxide in flue gas by iodometry[J]. Technical Supervision of Petroleum Industry, 2015, 31(8): 38-39(in Chinese). |
[10] |
SHAN X P, GU R F, SONG Q M, et al. Flame photometric determination of total sulfur and non-sulfur dioxide total sulfur in carbon dioxide[J]. Low Temperature and Specialty Gases, 2015, 33(2): 46-50(in Chinese). |
[11] |
ZHAO W Y, GUO J X, YIN H Q. Research status and development trend of atmospheric SO2 monitoring technology[J]. Sichuan Che-mical Industry, 2012, 15(6): 20-23(in Chinese). |
[12] |
LI M M.The key technique on detecting the concentration of sulfur dioxode with optical method[D]. Qinhuangdao: Yanshan University, 2014: 5-7(in Chinese). |
[13] |
JIAN X.Reseaech on sulfur dioxide concentration detection based on fluorescenr technology[D]. Qinhuangdao: Yanshan University, 2013: 4-8(in Chinese). |
[14] |
ZOU Y M, YANG Y W. Research progress in fluorescence detection technology of sulfur dioxide in air pollutants[J]. Shanghai Chemical Industry, 2019, 44 (4):39-43(in Chinese). |
[15] |
LIU J H, LI X. The fluorescence acquisition path of sulfur dioxide is designed and simulated by ZEMAX[J]. Laser Technology, 2020, 44(2):221-225(in Chinese). |
[16] |
ZOU Y M, YANG Y W.Research progress in fluorescence detection technology of sulfur dioxide in air pollutants[J]. Shanghai Chemical Industry, 2019, 44(4):39-43(in Chinese). |
[17] |
EIHADDAD M T, TAO Y K. Non-contact characterization of compound optical elements using reflectance confocal microscopy, low-coherence interferometry, and computational ray-tracing[J]. Scientific Reports, 2019, 9(1):261-271. |
[18] |
WANG Sh T, WANG Zh F, LIU M H, et al. Study on methane and sulfur dioxide detection system based on spectral absorption and fluorescence[J]. Spectroscopy and Spectral Analysis, 2016, 36(1): 287-291(in Chinese). |
[19] |
HANULIA T, INAMI W, ONO A, et al. Fluorescence. lifetime measurement excited with ultraviolet surface plasmon resonance[J].Optics Communications, 2018, 427:266-270. |
[20] |
DENG K, YANG H, WANG X Y. Geometric optical si-mulation based on comsol multiphysics[J]. Science and Technology of West China, 2015, 14(10):95-97(in Chinese). |