Content of issue 04, volume 33, 2020

1. Lukashevskaya A. A., Perevalov V. I. Databank of spectral line parameters of the H2S molecule. P. 241–249
Bibliographic reference:
Lukashevskaya A. A., Perevalov V. I. Databank of spectral line parameters of the H2S molecule. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 241–249. DOI: 10.15372/AOO20200401 [in Russian].
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Lukashevskaya A.A. and Perevalov V.I. Bank of Spectral Line Parameters of the H2S Molecule // Atmospheric and Oceanic Optics, 2020, V. 33. No. 05. pp. 449–458.
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2. Zhuravleva T. B., Artyushina A. V., Vinogradova A. A., Voronina Yu. V. Black carbon in the near-surface atmosphere far away from emission sources: comparison of measurements and MERRA-2 reanalysis data. P. 250–260
Bibliographic reference:
Zhuravleva T. B., Artyushina A. V., Vinogradova A. A., Voronina Yu. V. Black carbon in the near-surface atmosphere far away from emission sources: comparison of measurements and MERRA-2 reanalysis data. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 250–260. DOI: 10.15372/AOO20200402 [in Russian].
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3. Timofeev Yu. M., Berezin I. A., Virolainen Ya. A., Poberovsky A. V., Makarova M. V., Polyakov A. V. Estimates of anthropogenic CO2 emissions for Moscow and St. Petersburg based on OCO-2 satellite measurements. P. 261–265
Bibliographic reference:
Timofeev Yu. M., Berezin I. A., Virolainen Ya. A., Poberovsky A. V., Makarova M. V., Polyakov A. V. Estimates of anthropogenic CO2 emissions for Moscow and St. Petersburg based on OCO-2 satellite measurements. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 261–265. DOI: 10.15372/AOO20200403 [in Russian].
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4. Astafurov V. G., Skorokhodov A. V., Kuriyanovich K. V., Mitrofanenko Y. K. Parameters of various cloud types over the natural zones of Western Siberia according to MODIS satellite data. P. 266–271
Bibliographic reference:
Astafurov V. G., Skorokhodov A. V., Kuriyanovich K. V., Mitrofanenko Y. K. Parameters of various cloud types over the natural zones of Western Siberia according to MODIS satellite data. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 266–271. DOI: 10.15372/AOO20200404 [in Russian].
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Astafurov V.G., Skorokhodov A.V., Kur’yanovich K.V. and Mitrofanenko Ya.K. Parameters of Different Cloud Types over the Natural Zones of Western Siberia According to MODIS Satellite Data // Atmospheric and Oceanic Optics, 2020, V. 33. No. 05. pp. 512–518.
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5. Grebennikov V. S., Zubachev D. S., Korshunov V. A., Sakhibgareev D. G., Chernikh I.. A.. Observations of stratosphere aerosol at lidar stations of Roshydromet after the eruption of the Raikoke volcano in June 2019. P. 272–276
Bibliographic reference:
Grebennikov V. S., Zubachev D. S., Korshunov V. A., Sakhibgareev D. G., Chernikh I.. A.. Observations of stratosphere aerosol at lidar stations of Roshydromet after the eruption of the Raikoke volcano in June 2019. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 272–276. DOI: 10.15372/AOO20200405 [in Russian].
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Grebennikov V.S., Zubachev D.S., Korshunov V.A., Sakhibgareev D.G. and Chernikh I.A.Observations of Stratospheric Aerosol at Rosgidromet Lidar Stations after the Eruption of the Raikoke Volcano in June 2019 // Atmospheric and Oceanic Optics, 2020, V. 33. No. 05. pp. 519–523.
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6. Banakh V. A., Falits A. V. Impact of optical turbulence on the laser echo signal in the atmosphere. P. 277–288
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Banakh V. A., Falits A. V. Impact of optical turbulence on the laser echo signal in the atmosphere. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 277–288. DOI: 10.15372/AOO20200406 [in Russian].
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7. Razenkov I. A., Nadeev A. I., Zaitsev N. G., Gordeev E. V. Turbulent UV lidar BSE-5.. P. 289–297
Bibliographic reference:
Razenkov I. A., Nadeev A. I., Zaitsev N. G., Gordeev E. V. Turbulent UV lidar BSE-5.. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 289–297. DOI: 10.15372/AOO20200407 [in Russian].
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Razenkov I.A., Nadeev A.I., Zaitsev N.G. and Gordeev E.V. Turbulent UV Lidar BSE-5 // Atmospheric and Oceanic Optics, 2020, V. 33. No. 04. pp. 406–414.
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8. Vasilenko I. A., Sadovnikov S. A., RomanovskiI O. A. Assessment of the effect of spectroscopic information accuracy on the results of lidar measurements of methane using expert line lists. P. 298–301
Bibliographic reference:
Vasilenko I. A., Sadovnikov S. A., RomanovskiI O. A. Assessment of the effect of spectroscopic information accuracy on the results of lidar measurements of methane using expert line lists. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 298–301. DOI: 10.15372/AOO20200408 [in Russian].
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Vasilenko I. A., Sadovnikov S. A. and Romanovskii O. A. Estimation of the Effect of Spectroscopic Information Accuracy on the Lidar Measurements of Methane with the Use of Expert Line Lists // Atmospheric and Oceanic Optics, 2020, V. 33. No. 04. pp. 415–418.
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9. Myshkin V. F., Balandin S. F., Donchenko V. A., Pogodaev V. A., Khan V. A., Abramova E. S., Kulakov Yu. I., Pavlova M. S., Khazan V. L., Horohorin D. M. Generation of electric and magnetic fields in the high-intense laser radiation propagation in the atmosphere. P. 302–308
Bibliographic reference:
Myshkin V. F., Balandin S. F., Donchenko V. A., Pogodaev V. A., Khan V. A., Abramova E. S., Kulakov Yu. I., Pavlova M. S., Khazan V. L., Horohorin D. M. Generation of electric and magnetic fields in the high-intense laser radiation propagation in the atmosphere. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 302–308. DOI: 10.15372/AOO20200409 [in Russian].
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Myshkin V.F., Balandin S.F., Donchenko V.A., Pogodaev V.A., Khan V.A., Abramova E.S., Kulakov Yu.I., Pavlova M.S., Khazan V.L. and Horohorin D.M. Generation of Electric and Magnetic Fields during High-Intensity Laser Radiation Propagation through the Atmosphere // Atmospheric and Oceanic Optics, 2020, V. 33. No. 05. pp. 549–554.
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10. Nadeev A. I., Penner I. E., Shevtsov E. S. Photodetector module for recording lidar signals in the near-infrared region. P. 309–314
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Nadeev A. I., Penner I. E., Shevtsov E. S. Photodetector module for recording lidar signals in the near-infrared region. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 309–314. DOI: 10.15372/AOO20200410 [in Russian].
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Nadeev A.I., Penner I.E. and Shevtsov E.S. Photodetector Module for Recording Lidar Signals in the Near-Infrared Region // Atmospheric and Oceanic Optics, 2020, V. 33. No. 04. pp. 400–405.
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11. Znamenskii I. V., Tikhomirov A. A. Calculation of transmittance attenuation of infrared radiation stream on slant paths in the atmosphere, taking into account the sphericity of the Earth's surface. P. 315–320
Bibliographic reference:
Znamenskii I. V., Tikhomirov A. A. Calculation of transmittance attenuation of infrared radiation stream on slant paths in the atmosphere, taking into account the sphericity of the Earth's surface. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 315–320. DOI: 10.15372/AOO20200411 [in Russian].
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12. Kuzmichev A. S., Nadezhdinskii A. I., Ponurovskii Ya. Ya., Stavrovskii D. B., Shapovalov Yu. P., Khattatov V. U., Galaktionov V. V. The first results of measuring carbon dioxide and methane concentrations by diode laser spectroscopy in various regions of the Russian Federation from the board of the Yak-42D Roshydromet aircraft laboratory. P. 321–325
Bibliographic reference:
Kuzmichev A. S., Nadezhdinskii A. I., Ponurovskii Ya. Ya., Stavrovskii D. B., Shapovalov Yu. P., Khattatov V. U., Galaktionov V. V. The first results of measuring carbon dioxide and methane concentrations by diode laser spectroscopy in various regions of the Russian Federation from the board of the Yak-42D Roshydromet aircraft laboratory. // Optika Atmosfery i Okeana. 2020. V. 33. No. 04. P. 321–325. DOI: 10.15372/AOO20200412 [in Russian].
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13. Information. P. 326