Vol. 30, issue 03, article # 3

Ageev B. G., Klimkin A. V., Kuryak A. N., Osipov K. Yu., Ponomarev Yu. N. Remote detector of hazardous substances based on a tunable 13С16О2 laser. // Optika Atmosfery i Okeana. 2017. V. 30. No. 03. P. 204–208. DOI: 10.15372/AOO20170303 [in Russian].
Copy the reference to clipboard

Abstract:

Description of the developed prototype of a remote detector of hazardous substance vapors based on a tunable 13С16О2 laser is given. Results of test measurements of laser radiation transmission of organic liquid vapors (acetone, ammonia, ethanol, gasoline) are presented. The remote detection of acetone and ammonia vapors at distances up to 100 m is experimentally implemented.

Keywords:

remote detection, 13С16О2 laser, hazardous substances

References:

  1. Munson C.A., Gottfried J.L., De Lucia F.C., McNesby K.L., Miziolek A.W. Laser-Based Detection Methods for Explosives. Rep. N ADA474060. Army Research Lab Aberdeen Proving Ground MD Weapons and Materials Research Directorate, 2007. 76 p.
  2. Steinfeld J.I., Wormhoudt J. Explosives detection: A challenge for physical chemistry // Annu. Rev. Phys. Chem. 1998. V. 49. P. 203–232.
  3. Nakamoto K. Infrared and Raman Spectra of Inorganic and Coordination Compounds. Part A&B. N.Y.: Wiley-Interscience, 2008. 1000 p.
  4. Nabiev Sh.Sh., Stavrovskij  D.B., Palkina L.A., Zbarskij V.L., Judin N.V., Golubeva E.N., Vaks V.L., Domracheva E.G., Sobakinskaja E.A., Chernjaeva M.B. Spektrohimicheskie osobennosti nekotoryh brizantnyh vzryvchatyh veshhestv v paroobraznom sostojanii // Optika atmosf. i okeana. 2013. V. 26, N 4. P. 273–285; Nabiev Sh.Sh. Stavrovskii D.B., Pal-kina L.A., Zbarskii V.L., Yudin N.V., Golubeva E.N., Waks V.L., Domracheva E.G., Sobakinskaya E.A., Chernyaeva M.B. Spectrochemical features of certain brisant explosives in the vapor state // Atmos. Ocean. Opt. 2013. V. 26, N 5. P. 377–390.
  5. Starovojtov V.S., Trushin S.A., Churakov V.V. Optiko-akusticheskij gazoanalizator mnogokomponentnogo zagrjaznenija vozduha na osnove 13C16O2-lazera // Zh. prikl. spektroskopii. 1999. V. 66, N 3. P. 345–350.
  6. Starovojtov V.S., Trushin S.A., Churakov V.V. Ispol'zovanie lazerov na izotopozameshhennyh molekulah CO2 pri optiko-akusticheskom kontrole zagrjaznenija atmosfery // Zh. prikl. spektroskopii. 1993. V. 59, N 5–6. P. 504–509.
  7. Pal A., Clark C.D., Sigman M., Killinger D.K. Differential absorption lidar CO2 laser system for remote sensing of TATP related gases // Appl. Opt. 2009. V. 48, N 4. P. B145–B150.
  8. Sakovich G.V., Chernov A.I., Silant'ev S.V., Vorozhcov A.B., Pavlenko A.A., Maksimenko E.V., Makogon M.M., Klimkin A.V., Osipov K.Ju., Ponomarev Ju.N., Kapitanov V.A., Ageev B.G. Maket distancionnogo detektora vzryvchatyh veshhestv na osnove izotopnogo CO2-lazera // Polzunovskij vestnik. 2010. N 4. P. 38–46.
  9. http://www.detectors.lc-solutions.com/