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G. Mégie (1987)
Laser Monitoring in the Atmosphere
L. A. Skvortsov (2014)
Laser Techniques for Remote Detection of Chemical Compounds on the Body Surface
B. Ageev, A. Klimkin, A. Kuryak, K. Osipov, Y. Ponomarev (2017)
Remote detector of hazardous substances based on a tunable 13С16О2 laserAtmospheric and Oceanic Optics, 30
J. Carter, S. Angel, M. Lawrence-Snyder, J. Scaffidi, Richard Whipple, John Reynolds (2005)
Standoff Detection of High Explosive Materials at 50 Meters in Ambient Light Conditions Using a Small Raman InstrumentApplied Spectroscopy, 59
S. Bobrovnikov, A. Vorozhtsov, E. Gorlov, V. Zharkov, E. Maksimov, Y. Panchenko, G. Sakovich (2016)
Lidar Detection of Explosive Vapors in the AtmosphereRussian Physics Journal, 58
(2001)
A unique scheme for remote detection of explosives,” Appl
Narrow - band tunable laser for a lidar facility
P. Jander, R. Noll (2009)
Automated Detection of Fingerprint Traces of High Explosives Using Ultraviolet Raman SpectroscopyApplied Spectroscopy, 63
A. Pettersson, I. Johansson, S. Wallin, M. Nordberg, H. Östmark (2009)
Near Real‐Time Standoff Detection of Explosives in a Realistic Outdoor Environment at 55 m DistancePropellants, Explosives, Pyrotechnics, 34
R. Chirico, S. Almaviva, F. Colao, L. Fiorani, M. Nuvoli, W. Schweikert, F. Schnürer, Luigi Cassioli, S. Grossi, D. Murra, I. Menicucci, F. Angelini, A. Palucci (2015)
Proximal Detection of Traces of Energetic Materials with an Eye-Safe UV Raman Prototype Developed for Civil ApplicationsSensors (Basel, Switzerland), 16
A. Pettersson, S. Wallin, H. Östmark, A. Ehlerding, I. Johansson, M. Nordberg, Hanna Ellis, A. Al-Khalili (2010)
Explosives standoff detection using Raman spectroscopy: from bulk towards trace detection, 7664
T. Seuthe, M. Grehn, A. Mermillod-Blondin, H. Eichler, J. Bonse, M. Eberstein (2013)
Structural modifications of binary lithium silicate glasses upon femtosecond laser pulse irradiation probed by micro-Raman spectroscopyOptical Materials Express, 3
S. Bobrovnikov, E. Gorlov, V. Zharkov, Y. Panchenko, A. Puchikin (2018)
Dynamics of the laser fragmentation/laser-induced fluorescence process in nitrobenzene vapors.Applied optics, 57 31
C. Wynn, S. Palmacci, R. Kunz, M. Rothschild (2010)
Noncontact detection of homemade explosive constituents via photodissociation followed by laser-induced fluorescence.Optics express, 18 6
SanPiN 5804-91. Sanitary Norms and Rules of Laser Design and Operation (Moscow, 1992)
A. Pettersson, I. Johansson, S. Wallin, M. Nordberg, H. Ostmark (2009)
“Near real time standoff detection of explosives in a realistic outdoor environment at 55 m distance,” Propellants, ExploPyrotech., 34
W. Al-Saidi, S. Asher, P. Norman (2012)
Resonance Raman spectra of TNT and RDX using vibronic theory, excited-state gradient, and complex polarizability approximations.The journal of physical chemistry. A, 116 30
J. Moros, J. Lorenzo, K. Novotný, J. Laserna (2013)
Fundamentals of stand‐off Raman scattering spectroscopy for explosive fingerprintingJournal of Raman Spectroscopy, 44
G. Gresham, J. Davies, L. Goodrich, L. Blackwood, Benjamin Liu, D. Thimsen, S. Yoo, S. Hallowell (1994)
Development of particle standards for testing detection systems: mass of RDX and particle size distribution of composition 4 residues, 2276
J. Malicet, D. Daumont, J. Charbonnier, C. Parisse, A. Chakir, J. Brion (1995)
Ozone UV spectroscopy. II. Absorption cross-sections and temperature dependenceJournal of Atmospheric Chemistry, 21
T. Arusi-Parpar, D. Heflinger, R. Lavi (2001)
Photodissociation followed by laser-induced fluorescence at atmospheric pressure and 24 degrees C: a unique scheme for remote detection of explosives.Applied optics, 40 36
(2013)
Experimental estimation of the sensitivity of the UV Raman lidar
S. Bobrovnikov, E. Gorlov, V. Zharkov (2017)
Remote detection of traces of high-energy materials on an ideal substrate using the Raman effectAtmospheric and Oceanic Optics, 30
M. Gaft, L. Nagli (2008)
UV gated Raman spectroscopy for standoff detection of explosivesOptical Materials, 30
(2010)
From bulk towards trace detection,” Proc
S. Bobrovnikov, E. Gorlov, V. Zharkov (2018)
Technique for Increasing the Selectivity of the Method of Laser Fragmentation/Laser-Induced FluorescenceRussian Physics Journal, 61
(1994)
Mass of RDX and particle size distribution of composition 4 residues,” Proc
A. Yadav, Prabhakar Singh (2015)
A review of the structures of oxide glasses by Raman spectroscopyRSC Advances, 5
GOST 31581 - 2012 . Laser Safety . General Safety Requirements for the Design and Operation of Laser Devices ( Standartinform , Moscow , 2013 ) [ in Russian ]
M. Baldin, S. Bobrovnikov, A. Vorozhtsov, E. Gorlov, V. Gruznov, V. Zharkov, Y. Panchenko, M. Pryamov, G. Sakovich (2019)
Effectiveness of Combined Laser and Gas Chromatographic Remote Detection of Traces of ExplosivesAtmospheric and Oceanic Optics, 32
Y. Fleger, L. Nagli, M. Gaft, M. Rosenbluh (2009)
Narrow gated Raman and luminescence of explosivesJournal of Luminescence, 129
(2014)
Laser Techniques for Remote Detection of Chemical Compounds on the Body Surface (Tekhnosfera
R. Forest, F. Babin, D. Gay, N. Hô, O. Pancrati, Simon Deblois, S. Désilets, J. Maheux (2012)
Use of a spectroscopic lidar for standoff explosives detection through Raman spectra, 8358
ISSN 1024-8560, Atmospheric and Oceanic Optics, 2019, Vol. 32, No. 3, pp. 361–365. © Pleiades Publishing, Ltd., 2019. Russian Text © The Author(s), 2019, published in Optika Atmosfery i Okeana. OPTICAL INSTRUMENTATION Inf luence of Substrate Material on the Sensitivity of the Raman Lidar Technique for Detecting Traces of High-Energy Materials a, b, a, b a, S. M. Bobrovnikov *, E. V. Gorlov , and V. I. Zharkov ** V.E. Zuev Institute of Atmospheric Optics, Siberian Branch, Russian Academy of Sciences, Tomsk, 634055 Russia Tomsk State University, Tomsk, 634050 Russia *e-mail: bsm@iao.ru **e-mail: zharkov@iao.ru Received December 5, 2018; revised December 5, 2018; accepted January 23, 2019 Abstract—Experimental results on the remote detection of surface traces of some high-energy materials are presented. The detection was performed with the use of a Raman lidar based on a narrow-linewidth excimer KrF laser and a multichannel spectrum analyzer with diffraction spectrograph and time-gated ICCD camera. The sensitivity of the lidar system is estimated for a detection range of 10 m. The inf luence of a substrate material on the detection sensitivity is analyzed. Keywords: lidar, Raman scattering, remote detection, high-energy materials DOI: 10.1134/S1024856019030035 INTRODUCTION these situations is limited by the requirements for safe
Atmospheric and Oceanic Optics – Springer Journals
Published: Jun 17, 2019
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