Content of issue 08, volume 30, 2017

  1. Banakh V.A., Smalikho I.N. Estimation of the turbulence energy dissipation rate in the atmospheric boundary layer based on measurements of wind radial velocity by a micropulsed coherent Doppler lidar. I. Numerical analysis. P. 631–637
    Bibliographic reference:
    Banakh V.A., Smalikho I.N. Estimation of the turbulence energy dissipation rate in the atmospheric boundary layer based on measurements of wind radial velocity by a micropulsed coherent Doppler lidar. I. Numerical analysis. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 631–637 [in Russian].
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  2. Banakh V.A., Smalikho I.N., Falits A.V. Estimation of the turbulence energy dissipation rate in the atmospheric boundary layer based on measurements of wind radial velocity by a micropulsed coherent Doppler lidar. II. Experiment. P. 638–643
    Bibliographic reference:
    Banakh V.A., Smalikho I.N., Falits A.V. Estimation of the turbulence energy dissipation rate in the atmospheric boundary layer based on measurements of wind radial velocity by a micropulsed coherent Doppler lidar. II. Experiment. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 638–643 [in Russian].
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  3. Banakh V.A., Smalikho I.N., Falits A.V., Gordeev E.V., Sukharev A.A. Stream Line Doppler lidar measurements of wind speed and direction with the duo-beam method in the atmospheric boundary layer. P. 644–650
    Bibliographic reference:
    Banakh V.A., Smalikho I.N., Falits A.V., Gordeev E.V., Sukharev A.A. Stream Line Doppler lidar measurements of wind speed and direction with the duo-beam method in the atmospheric boundary layer. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 644–650 [in Russian].
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    Banakh V.A., Smalikho I.N., Falits A.V., Gordeev E.V. and Sukharev A.A. Stream Line Doppler Lidar Measurements of Wind Speed and Direction with the Duo-Beam Method in the Surface Air Layer. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 06. pp. 581–587.
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  4. Afanas'ev A.L., Banakh V.A., Marakasov D.A. Comparative estimates of the transversal wind velocity component from optical and acoustic measurements in the surface air layer. P. 651–657
    Bibliographic reference:
    Afanas'ev A.L., Banakh V.A., Marakasov D.A. Comparative estimates of the transversal wind velocity component from optical and acoustic measurements in the surface air layer. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 651–657 [in Russian].
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    Afanasiev A.L., Banakh V.A. and Marakasov D.A. Comparative Assessments of the Crosswind Speed from Optical and Acoustic Measurements in the Surface Air Layer. // Atmospheric and Oceanic Optics, 2018, V. 31. No. 01. pp. 43–48.
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  5. Afanas'ev A.L., Banakh V.A., Gordeev E.V., Marakasov D.A., Sukharev A.A., Falits A.V. Verification of passive correlation optical crosswind velocity meter in experiments with Doppler wind lidar. P. 657–663
    Bibliographic reference:
    Afanas'ev A.L., Banakh V.A., Gordeev E.V., Marakasov D.A., Sukharev A.A., Falits A.V. Verification of passive correlation optical crosswind velocity meter in experiments with Doppler wind lidar. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 657–663 [in Russian].
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    Afanasiev A.L., Banakh V.A., Gordeev E.V., Marakasov D.A., Sukharev A.A. and Falits A.V. Verification of a Passive Correlation Optical Crosswind Velocity Meter in Experiments with a Doppler Wind Lidar. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 06. pp. 574–580.
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  6. Smalikho I.N., Banakh V.A., Falits A.V. Measurements of aircraft wake vortex parameters by a Stream Line Doppler lidar. P. 664–671
    Bibliographic reference:
    Smalikho I.N., Banakh V.A., Falits A.V. Measurements of aircraft wake vortex parameters by a Stream Line Doppler lidar. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 664–671 [in Russian].
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    Smalikho I.N., Banakh V.A. and Falits A.V. Measurements of Aircraft Wake Vortex Parameters by a Stream Line Doppler Lidar. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 06. pp. 588–595.
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  7. Lukin I.P. Coherence of Bessel-Gaussian beams propagating in the turbulent atmosphere. P. 672–681
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    Lukin I.P. Coherence of Bessel-Gaussian beams propagating in the turbulent atmosphere. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 672–681 [in Russian].
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    Lukin I.P. Coherence of Bessel-Gaussian Beams Propagating in a Turbulent Atmosphere. // Atmospheric and Oceanic Optics, 2018, V. 31. No. 01. pp. 49–59.
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  8. Dudorov V.V., Eremina A.S. Retrieval of crosswind velocity based on the analysis of remote object images. Part 2. Drift of turbulent volume. P. 682–690
    Bibliographic reference:
    Dudorov V.V., Eremina A.S. Retrieval of crosswind velocity based on the analysis of remote object images. Part 2. Drift of turbulent volume. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 682–690 [in Russian].
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    Dudorov V.V. and Eremina A.S. Retrieval of Crosswind Velocity Based on the Analysis of Remote Object Images: Part 2–Drift of Turbulent Volume. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 06. pp. 596–603.
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  9. Bobrovnikov S.M., Gorlov E.V., Zharkov V.I. Remote detection of traces of high energetic materials on an ideal substrate using the Raman effect. P. 691–695
    Bibliographic reference:
    Bobrovnikov S.M., Gorlov E.V., Zharkov V.I. Remote detection of traces of high energetic materials on an ideal substrate using the Raman effect. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 691–695 [in Russian].
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    Bobrovnikov S.M., Gorlov E.V. and Zharkov V.I. Remote Detection of Traces of High-Energy Materials on an Ideal Substrate Using the Raman Effect. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 06. pp. 604–608.
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  10. Veretennikov V.V. Retrieval of microstructure parameters of coarse aerosol using their regression relationships with spectral extinction of light in the IR. P. 696–704
    Bibliographic reference:
    Veretennikov V.V. Retrieval of microstructure parameters of coarse aerosol using their regression relationships with spectral extinction of light in the IR. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 696–704 [in Russian].
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    Veretennikov V.V. Retrieval of Microstructure Parameters of Coarse-Mode Aerosol Using Their Regression Relationships with Spectral Extinction of Light in the IR. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 06. pp. 554–563.
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  11. Veretennikov V.V. Interannual variability of aerosol microstructure parameters retrieved from the data of solar photometry in Tomsk. P. 705–715
    Bibliographic reference:
    Veretennikov V.V. Interannual variability of aerosol microstructure parameters retrieved from the data of solar photometry in Tomsk. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 705–715 [in Russian].
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    Veretennikov V.V. Interannual Variations in Aerosol Microstructure Parameters according to Data of Sun Photometer Measurements in Tomsk. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 06. pp. 564–573.
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  12. Arshinov M.Yu., Belan B.D., Voronetskaya N.G., Golovko A.K., Davydov D.K., Kozlov A.S., Pevneva G.S., Simonenkov D.V., Fofonov A.V. Organic aerosol in air of Siberia and the Arctic. Part 1. Geographic features and temporal dynamics. P. 716–722
    Bibliographic reference:
    Arshinov M.Yu., Belan B.D., Voronetskaya N.G., Golovko A.K., Davydov D.K., Kozlov A.S., Pevneva G.S., Simonenkov D.V., Fofonov A.V. Organic aerosol in air of Siberia and the Arctic. Part 1. Geographic features and temporal dynamics. // Optika Atmosfery i Okeana. 2017. V. 30. No. 08. P. 716–722 [in Russian].
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  13. Personalia. P. 723–724