Content of issue 11, volume 33, 2020

1. Zаdvornykh I. V., Gribanov K. G., Denisova N. Yu., Zakharov V. I., Imasu R. Method for retrieval of HDO/H2O ratio vertical profile in the atmosphere from satellite spectra simultaneously measured in two spectral ranges: thermal and near-IR. P. 831–835
Bibliographic reference:
Zаdvornykh I. V., Gribanov K. G., Denisova N. Yu., Zakharov V. I., Imasu R. Method for retrieval of HDO/H2O ratio vertical profile in the atmosphere from satellite spectra simultaneously measured in two spectral ranges: thermal and near-IR. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 831–835. DOI: 10.15372/AOO20201101 [in Russian].
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2. Timofeev Yu. M., Filippov N. N., Poberovsky A. V. Analysis of the information content and vertical resolution of the ground-based spectroscopic IR method for the CO2 vertical structure retrieval. P. 836–841
Bibliographic reference:
Timofeev Yu. M., Filippov N. N., Poberovsky A. V. Analysis of the information content and vertical resolution of the ground-based spectroscopic IR method for the CO2 vertical structure retrieval. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 836–841. DOI: 10.15372/AOO20201102 [in Russian].
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3. Ageev B. G., Sapozhnikova V. A., Gruzdev A. N. About the possibility of the conifers contribution to interannual CO2 variations in the atmosphere. P. 842–848
Bibliographic reference:
Ageev B. G., Sapozhnikova V. A., Gruzdev A. N. About the possibility of the conifers contribution to interannual CO2 variations in the atmosphere. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 842–848. DOI: 10.15372/AOO20201103 [in Russian].
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4. Voronin B. A. Method of estimation of self-broadening parameters of spectroscopic lines on the example of the 32S16O2 molecule. P. 849–853
Bibliographic reference:
Voronin B. A. Method of estimation of self-broadening parameters of spectroscopic lines on the example of the 32S16O2 molecule. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 849–853. DOI: 10.15372/AOO20201104 [in Russian].
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5. Smalikho I. N., Banakh V. A., Falits A. V., Sukharev A. A., Gordeev E. V. Taking into account the wind transfer of turbulent inhomogeneities when estimating the turbulent energy dissipation rate from measurements with a conically scanning coherent Doppler lidar. Part II. Experiment. P. 854–862
Bibliographic reference:
Smalikho I. N., Banakh V. A., Falits A. V., Sukharev A. A., Gordeev E. V. Taking into account the wind transfer of turbulent inhomogeneities when estimating the turbulent energy dissipation rate from measurements with a conically scanning coherent Doppler lidar. Part II. Experiment. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 854–862. DOI: 10.15372/AOO20201105 [in Russian].
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6. Mankovsky V. I., Mankovskaya E. V. Determination of the size of suspended organic particles from light scattering phase function and their relationship to the water trophic state. P. 864–867
Bibliographic reference:
Mankovsky V. I., Mankovskaya E. V. Determination of the size of suspended organic particles from light scattering phase function and their relationship to the water trophic state. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 864–867. DOI: 10.15372/AOO20201106 [in Russian].
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7. Bychkov V. V., Seredkin I. N., Marichev V. N. Scattering on excited ions as a reason for registering an imaginary aerosol in the middle atmosphere. P. 867–873
Bibliographic reference:
Bychkov V. V., Seredkin I. N., Marichev V. N. Scattering on excited ions as a reason for registering an imaginary aerosol in the middle atmosphere. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 867–873. DOI: 10.15372/AOO20201107 [in Russian].
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8. Razenkov I. A. Experimental estimation of the backscatter enhancement peak. P. 874–879
Bibliographic reference:
Razenkov I. A. Experimental estimation of the backscatter enhancement peak. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 874–879. DOI: 10.15372/AOO20201108 [in Russian].
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9. Odintsov S. L., Gladkikh V. A., Kamardin A. P., Nevzorova I. V. Height of the zone of intense turbulent heat exchange in the stably stratified atmospheric boundary layer. Part  2: Relation to the surface meteorological parameters. P. 880–889
Bibliographic reference:
Odintsov S. L., Gladkikh V. A., Kamardin A. P., Nevzorova I. V. Height of the zone of intense turbulent heat exchange in the stably stratified atmospheric boundary layer. Part  2: Relation to the surface meteorological parameters. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 880–889. DOI: 10.15372/AOO20201109 [in Russian].
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10. Znamenskii I. V., Tikhomirov A. A. Algorithm and software for calculation of an IR optoelectronic system with a photodetector array. P. 890–896
Bibliographic reference:
Znamenskii I. V., Tikhomirov A. A. Algorithm and software for calculation of an IR optoelectronic system with a photodetector array. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 890–896. DOI: 10.15372/AOO20201110 [in Russian].
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11. Tarasenko V. F., Kuznetsov V. S., Baksht E. H., Panarin V. A., Skakun V. S., Sosnin E. A. Formation of ball and cylindrical streamers during corona discharge in air at atmospheric pressure. P. 897–904
Bibliographic reference:
Tarasenko V. F., Kuznetsov V. S., Baksht E. H., Panarin V. A., Skakun V. S., Sosnin E. A. Formation of ball and cylindrical streamers during corona discharge in air at atmospheric pressure. // Optika Atmosfery i Okeana. 2020. V. 33. No. 11. P. 897–904. DOI: 10.15372/AOO20201111 [in Russian].
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