Content of issue 03, volume 34, 2021

1. Petrova T. M., Solodov A. M., Shcherbakov A. P., Dеichuli V. M., Solodov A. A., Ponomarev Yu. N. Comparison of profile models for water vapor absorption lines. P. 159–163
Bibliographic reference:
Petrova T. M., Solodov A. M., Shcherbakov A. P., Dеichuli V. M., Solodov A. A., Ponomarev Yu. N. Comparison of profile models for water vapor absorption lines. // Optika Atmosfery i Okeana. 2021. V. 34. No. 03. P. 159–163. DOI: 10.15372/AOO20210301 [in Russian].
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Petrova T.M., Solodov A.M., Shcherbakov A.P., Deichuli V.M., Solodov A.A. and Ponomarev Yu.N. Comparison of Profile Models for Water Vapor Absorption Lines // Atmospheric and Oceanic Optics, 2021, V. 34. No. 04. pp. 283–287.
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2. Rodimova O. B. Absorption coefficient and intermolecular vibrations in the СО–Ar system. P. 164–168
Bibliographic reference:
Rodimova O. B. Absorption coefficient and intermolecular vibrations in the СО–Ar system. // Optika Atmosfery i Okeana. 2021. V. 34. No. 03. P. 164–168. DOI: 10.15372/AOO20210302 [in Russian].
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Rodimova O.B. Absorption Coefficient and Intermolecular Vibrations in the СО–Ar System // Atmospheric and Oceanic Optics, 2021, V. 34. No. 04. pp. 288–292.
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3. Banakh V. A., Smalikho I. N., Falits A. V. Determination of the height of the turbulent mixing air layer based on estimation of the parameters of wind turbulence from lidar data. P. 169–184
Bibliographic reference:
Banakh V. A., Smalikho I. N., Falits A. V. Determination of the height of the turbulent mixing air layer based on estimation of the parameters of wind turbulence from lidar data. // Optika Atmosfery i Okeana. 2021. V. 34. No. 03. P. 169–184. DOI: 10.15372/AOO20210303 [in Russian].
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4. Sukharev A. A., Banakh V. A. Compensation for aberration distortions of a laser beam wavefront by aero-optical effects on aircraft – satellite paths based on backscatter signals. P. 185–191
Bibliographic reference:
Sukharev A. A., Banakh V. A. Compensation for aberration distortions of a laser beam wavefront by aero-optical effects on aircraft – satellite paths based on backscatter signals. // Optika Atmosfery i Okeana. 2021. V. 34. No. 03. P. 185–191. DOI: 10.15372/AOO20210304 [in Russian].
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Sukharev A.A. and Banakh V.A. Compensation for Laser Beam Wavefront Aberration Distortions Induced by Aero-Optical Effects along Aircraft–Satellite Paths Based on Backscatter Signals // Atmospheric and Oceanic Optics, 2021, V. 34. No. 04. pp. 313–319.
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5. Zenkova P. N., Terpugova S. A., Pol'kin V. V., Pol'kin Vas. V., Uzhegov V. N., Kozlov V. S., Yausheva E. P., Panchenko M. V. Development of the empirical model of optical characteristics of aerosol in Western Siberia. P. 192–198
Bibliographic reference:
Zenkova P. N., Terpugova S. A., Pol'kin V. V., Pol'kin Vas. V., Uzhegov V. N., Kozlov V. S., Yausheva E. P., Panchenko M. V. Development of the empirical model of optical characteristics of aerosol in Western Siberia. // Optika Atmosfery i Okeana. 2021. V. 34. No. 03. P. 192–198. DOI: 10.15372/AOO20210305 [in Russian].
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Zenkova P.N., Terpugova S.A., Pol’kin V.V., Pol’kin Vas.V., Uzhegov V.N., Kozlov V.S., Yausheva E.P. and Panchenko M.V. Development of an Empirical Model of Optical Characteristics of Aerosol in Western Siberia // Atmospheric and Oceanic Optics, 2021, V. 34. No. 04. pp. 320–326.
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6. Tkachev I. V., Timofeev D. N., Kustova N. V., Konoshonkin A. V. Databank of Mueller matrices on atmospheric ice crystals of 10–100 mm for interpretation of ground-based and space-borne lidar data. P. 199–206
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Tkachev I. V., Timofeev D. N., Kustova N. V., Konoshonkin A. V. Databank of Mueller matrices on atmospheric ice crystals of 10–100 mm for interpretation of ground-based and space-borne lidar data. // Optika Atmosfery i Okeana. 2021. V. 34. No. 03. P. 199–206. DOI: 10.15372/AOO20210306 [in Russian].
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7. Lukin V. P., Konyaev P. A., Borzilov A. G., Soin E. L. Adaptive imaging and stabilization system for a large-aperture solar telescope. P. 207–217
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Lukin V. P., Konyaev P. A., Borzilov A. G., Soin E. L. Adaptive imaging and stabilization system for a large-aperture solar telescope. // Optika Atmosfery i Okeana. 2021. V. 34. No. 03. P. 207–217. DOI: 10.15372/AOO20210307 [in Russian].
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8. Trigub M. V., Dimaki V. A., Troitskii V. O., Karasev N. V. Increase in the CuBr-laser pulse duration in the pulse train mode. P. 218–222
Bibliographic reference:
Trigub M. V., Dimaki V. A., Troitskii V. O., Karasev N. V. Increase in the CuBr-laser pulse duration in the pulse train mode. // Optika Atmosfery i Okeana. 2021. V. 34. No. 03. P. 218–222. DOI: 10.15372/AOO20210308 [in Russian].
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Trigub M.V., Dimaki V.A., Troitskii V.O. and Karasev N.V. Increase in the CuBr Laser Pulse Duration in the Pulse Train Mode // Atmospheric and Oceanic Optics, 2021, V. 34. No. 04. pp. 357–361.
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9. Egorenko M. P., Efremov V. S. Three-range panoramic catadioptric navigation video camera system for unmanned miniature drones. P. 223–225
Bibliographic reference:
Egorenko M. P., Efremov V. S. Three-range panoramic catadioptric navigation video camera system for unmanned miniature drones. // Optika Atmosfery i Okeana. 2021. V. 34. No. 03. P. 223–225. DOI: 10.15372/AOO20210309 [in Russian].
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Egorenko M.P. and Efremov V.S. A Three-Range Panoramic Catadioptric Navigation Video Camera System for Unmanned Miniature Drones // Atmospheric and Oceanic Optics, 2021, V. 34. No. 04. pp. 362–365.
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10. Ageev B. G., Sapozhnikova V. A., Savchuk D. A. Changes in the radial growth and distribution of CO2 in larches survived the explosion of the Tunguska space body. P. 226–231
Bibliographic reference:
Ageev B. G., Sapozhnikova V. A., Savchuk D. A. Changes in the radial growth and distribution of CO2 in larches survived the explosion of the Tunguska space body. // Optika Atmosfery i Okeana. 2021. V. 34. No. 03. P. 226–231. DOI: 10.15372/AOO20210310 [in Russian].
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Ageev B.G., Sapozhnikova V.A. and Savchuk D.A. Changes in the Radial Increment and CO2 Distribution in Larches that Survived the Explosion of the Tunguska Space Body // Atmospheric and Oceanic Optics, 2021, V. 34. No. 04. pp. 366–371.
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11. Information. P. 232–234