Content of issue 07, volume 32, 2019

  1. Chizhmakova I.S., Nikitin A.V. Potential energy surface of SF6. P. 511–515
    Bibliographic reference:
    Chizhmakova I.S., Nikitin A.V. Potential energy surface of SF6. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 511–515 [in Russian].
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  2. Solodov A.A., Petrova T.M., Ponomarev Yu.N., Solodov A.M., Shаlygin A.S. Rotational dependence of line half-windth for fundamental band of CO2 confined in nanoporous aerogel. P. 516–518
    Bibliographic reference:
    Solodov A.A., Petrova T.M., Ponomarev Yu.N., Solodov A.M., Shаlygin A.S. Rotational dependence of line half-windth for fundamental band of CO2 confined in nanoporous aerogel. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 516–518 [in Russian].
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  3. Ostrikov V.N., Plakhotnikov O.V., Kirienko A.V. Estimation of the spectral resolution of an imaging spectrometer from Fraunhofer's lines with the MODTRAN atmospheric model. P. 519–524
    Bibliographic reference:
    Ostrikov V.N., Plakhotnikov O.V., Kirienko A.V. Estimation of the spectral resolution of an imaging spectrometer from Fraunhofer's lines with the MODTRAN atmospheric model. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 519–524 [in Russian].
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  4. Samoilova S.V. Simultaneous reconstruction of the complex refractive index and the particle size distribution function from the lidar data: examination of the algorithms. P. 525–538
    Bibliographic reference:
    Samoilova S.V. Simultaneous reconstruction of the complex refractive index and the particle size distribution function from the lidar data: examination of the algorithms. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 525–538 [in Russian].
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  5. Panchenko M.V., Pol'kin V.V., Pol'kin Vas.V., Kozlov V.S., Yausheva E.P., Shmargunov V.P. The size distribution of the “dry matter” of particles in the surface air layer in suburbs of Tomsk within the empirical classification of “aerosol weather” types. P. 539–547
    Bibliographic reference:
    Panchenko M.V., Pol'kin V.V., Pol'kin Vas.V., Kozlov V.S., Yausheva E.P., Shmargunov V.P. The size distribution of the “dry matter” of particles in the surface air layer in suburbs of Tomsk within the empirical classification of “aerosol weather” types. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 539–547 [in Russian].
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  6. Kabanov D.M., Sakerin S.M., Turchinovich Yu.S. Interannual and seasonal variations in the atmospheric aerosol optical depth near Tomsk (1995–2018). P. 548–555
    Bibliographic reference:
    Kabanov D.M., Sakerin S.M., Turchinovich Yu.S. Interannual and seasonal variations in the atmospheric aerosol optical depth near Tomsk (1995–2018). // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 548–555 [in Russian].
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  7. Bazhenov O.E., El'nikov A.V., Sysoev S.M. Total ozone content over Tomsk in 1994–2017: results of statistical analysis. P. 556–561
    Bibliographic reference:
    Bazhenov O.E., El'nikov A.V., Sysoev S.M. Total ozone content over Tomsk in 1994–2017: results of statistical analysis. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 556–561 [in Russian].
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  8. Smalikho I.N. Taking into account of the ground effect on aircraft wake vortices when evaluating their circulation from lidar measurements. P. 562–575
    Bibliographic reference:
    Smalikho I.N. Taking into account of the ground effect on aircraft wake vortices when evaluating their circulation from lidar measurements. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 562–575 [in Russian].
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  9. Tatur V.V., Tikhomirov A.A., Abramochkin A.I., Korolev B.V., Мutnitskii N.G. Mercury vapor analyzer in atmospheric air based on mercury capillary lamp with natural isotope composition. P. 576–580
    Bibliographic reference:
    Tatur V.V., Tikhomirov A.A., Abramochkin A.I., Korolev B.V., Мutnitskii N.G. Mercury vapor analyzer in atmospheric air based on mercury capillary lamp with natural isotope composition. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 576–580 [in Russian].
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  10. Fedorov V.F., Trigub M.V., Sеmenov K.Yu., Shiyanov D.V., Vlasov V.V. The construction of the metal vapor active element. P. 581–584
    Bibliographic reference:
    Fedorov V.F., Trigub M.V., Sеmenov K.Yu., Shiyanov D.V., Vlasov V.V. The construction of the metal vapor active element. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 581–584 [in Russian].
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  11. Sosnin E.A., Baksht E.H., Kuznetsov V.S., Panarin V.A., Skakun V.S., Tarasenko V.F. Laboratory modeling of blue jets with apokamp discharge in Hz frequency range. P. 585–590
    Bibliographic reference:
    Sosnin E.A., Baksht E.H., Kuznetsov V.S., Panarin V.A., Skakun V.S., Tarasenko V.F. Laboratory modeling of blue jets with apokamp discharge in Hz frequency range. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 585–590 [in Russian].
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  12. Kolosov V.V., Levitsky M.E., Petukhov T.D., Simonova G.V. Formation of feedback loop for phase control of a fiber laser array. P. 591–598
    Bibliographic reference:
    Kolosov V.V., Levitsky M.E., Petukhov T.D., Simonova G.V. Formation of feedback loop for phase control of a fiber laser array. // Optika Atmosfery i Okeana. 2019. V. 32. No. 07. P. 591–598 [in Russian].
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