[1] Li Zhibo. The experimental research of minitype CO2 differential absorption lidar system[D]. Harbin: Harbin Institute of Technology, 2016. (in Chinese)
Li Zhibo. The experimental research of minitype CO2 differential absorption lidar system[D]. Harbin: Harbin Institute of Technology, 2016. (in Chinese)
[2] Tehrani M K, Mohammad M M, Jaafari E, et al. Setting up a mobile Lidar (DIAL) system for detecting chemical warfare agents[J]. Laser Physics, 2015, 25(3): 035701.
Tehrani M K, Mohammad M M, Jaafari E, et al. Setting up a mobile Lidar (DIAL) system for detecting chemical warfare agents[J]. Laser Physics, 2015, 25(3): 035701.
[3] Jaafari E, Mohammad M M, Tehrani M K. Promoting the range and range resolution of a LIDAR (DIAL) system using a suitable pinhole plasma shutter[J]. Journal of Russian Laser Research, 2017, 38(5): 446-454.
Jaafari E, Mohammad M M, Tehrani M K. Promoting the range and range resolution of a LIDAR (DIAL) system using a suitable pinhole plasma shutter[J]. Journal of Russian Laser Research, 2017, 38(5): 446-454.
[4] Tong Weihong, Jiang Dong, Zhou Dingfu, et al. Study on the chemical gas detecting system by CO2 DIAL[J]. Laser Technology, 2006, 31(5): 479-482. (in Chinese)
Tong Weihong, Jiang Dong, Zhou Dingfu, et al. Study on the chemical gas detecting system by CO2 DIAL[J]. Laser Technology, 2006, 31(5): 479-482. (in Chinese)
[6] Savovic J, Stoiljkovic M, Kuzmanovic M, et al. The feasibility of TEA CO2 laser-induced plasma for spectrochemical analysis of geological samples in simulated Martian conditions[J]. Spectrochimica Acta Part B Atomic Spectroscopy, 2016, 118: 127-136.
Savovic J, Stoiljkovic M, Kuzmanovic M, et al. The feasibility of TEA CO2 laser-induced plasma for spectrochemical analysis of geological samples in simulated Martian conditions[J]. Spectrochimica Acta Part B Atomic Spectroscopy, 2016, 118: 127-136.
[7] Zivkovic S, Momcilovic M, Staicu A, et al. Spectrochemical analysis of powdered biological samples using transversely excited atmospheric carbon dioxide laser plasma excitation[J]. Spectrochimica Acta Part B: Atomic Spectroscopy, 2017, 128: 22-29.
Zivkovic S, Momcilovic M, Staicu A, et al. Spectrochemical analysis of powdered biological samples using transversely excited atmospheric carbon dioxide laser plasma excitation[J]. Spectrochimica Acta Part B: Atomic Spectroscopy, 2017, 128: 22-29.
[8] Zivkovic S, Savovic J, Trtica M, et al. Elemental analysis of aluminum alloys by laser induced breakdown spectroscopy based on TEA CO2 laser[J]. Journal of Alloys & Compounds, 2017, 700:175-184.
Zivkovic S, Savovic J, Trtica M, et al. Elemental analysis of aluminum alloys by laser induced breakdown spectroscopy based on TEA CO2 laser[J]. Journal of Alloys & Compounds, 2017, 700:175-184.
[11] Karapuzikov A I, Ptashnik I V, Sherstov I V, et al. Modeling of helicopter-borne tunable TEA CO2 DIAL system employment for detection of methane and ammonia leakages[J]. Infrared Physics & Technology, 2000, 41(2): 87-96.
Karapuzikov A I, Ptashnik I V, Sherstov I V, et al. Modeling of helicopter-borne tunable TEA CO2 DIAL system employment for detection of methane and ammonia leakages[J]. Infrared Physics & Technology, 2000, 41(2): 87-96.
[12] Wu Jin, Wan Chongyi. TEA CO2 laser tuned by low fineness Fabry-Pertot interferometer[J]. Journal of Optoelectronics·Laser, 2002(4): 349-351. (in Chinese)
Wu Jin, Wan Chongyi. TEA CO2 laser tuned by low fineness Fabry-Pertot interferometer[J]. Journal of Optoelectronics·Laser, 2002(4): 349-351. (in Chinese)
[14] Cheng Yongqiang, Tan Rongqing, Chen Jing, et al. Investigation on rapidly tunable technology of grating line selection TEA CO2 laser[J]. Laser and Infrared, 2006, 36(4): 250-253. (in Chinese)
Cheng Yongqiang, Tan Rongqing, Chen Jing, et al. Investigation on rapidly tunable technology of grating line selection TEA CO2 laser[J]. Laser and Infrared, 2006, 36(4): 250-253. (in Chinese)