Source: http://ao.iao.ru/en/content/vol.22-2009/iss.05
Timestamp: 2019-04-19 00:27:13+00:00

Document:
Tvorogov S.D. Centre-of-mass problem in the spectral line shape task. I. Existence of long trajec-tories. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 413-419 [in Russian].
Tvorogov S.D. Problem of Centers of Mass within the Problem of the Contour of Spectral Lines.
1. Existence of Long Trajectories. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 257–263.
Kochanov V.P. . Light generation without population inversion in schemes of stimulated Raman and hyper-Raman scattering on allowed atomic transitions. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 420-427 [in Russian].
Kochanov V.P. Inversionless Generation of Radiation in Stimulated Raman and Hyper-Raman Scattering at Allowed Transitions in Atoms. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 264–272.
Buldakov M.A., Koryukina E.V., Cherepanov V.N. General regularities in the behavior of dipole moment functions of diatomic molecules at small internuclear separations. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 428-434 [in Russian].
Buldakov M.A., Koryukina E.V., and. Cherepanov V.N. General Regularities in the Behavior of Dipole Moment Functions of Diatomic .... // Atmospheric and Oceanic Optics, 2009, V. 22. No. 02. pp. 135–142.
Romanov N.P. A computational method and properties of phase scattering functions of transparent balls in the geometric optics approximation. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 435-444 [in Russian].
Romanov N.P. A Computational Method and Properties of Phase Scattering Functions of Transparent Balls under the Geometric Optics Approximation. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 273–283.
Sadykov N.R., Sсorkin N.A. Mathematical modeling of interaction of radiation with disperse nanoparticles. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 445-449 [in Russian].
Sadykov N.R. and Skorkin N.A. Mathematical Modeling of the Process of Interaction between Radiation and Disperse Nanoparticles. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 284–289.
Zuev V.V., Balin Yu.S., Bukin O.A., Burlakov V.D., Dolgii S.I., Kabashnikov V.P., Nevzorov A.V., Osipenko F.P., Pavlov A.N., Penner I.E., Samoilova S.V., Stolyarchuk S.Yu., Chaykovskii A.P., Shmirko K.A. Results of joint observations of aerosol perturbations in the stratosphere at stations of CIS-LiNet in 2008. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 450-456 [in Russian].
Zuev V.V., Balin Yu.S., Bukin O.A., Burlakov V.D., Dolgii S.I., Kabashnikov V.P., Nevzorov A.V., Osipenko F.P., Pavlov A.N., Penner I.E., Samoilova S.V., Stolyarchuk S.Yu., Chaikovskii A.P., and Shmirko K.A. Results of Joint Observations of Aerosol Perturbations of the Stratosphere at the CIS-LiNet Network in 2008. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 295–301.
Arshinov M.Yu., Belan B.D., Davydov D.K., Inoue Gen., Maksutov Shamil.Shamil., Machida Toshinobu., Fofonov A.V. Vertical distribution of greenhouse gases over West Siberia from long-term measurement data. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 457-464 [in Russian].
Matveev L.T., Matveev Yu.L., Nikolaeva E.Yu. Dynamic factors of Earth cloud formation. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 465-470 [in Russian].
Matveev L.T., Matveev Yu.L., and Nikolaeva E.Yu. Dynamic Factors in the Formation of the Earth’s Cloud Field. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 325–330.
Zolotov S.Yu., Ippolitov I.I., Loginov S.V. Estimation of changes of surface air temperature with the use of the method of wavelet-transformation. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 471-475 [in Russian].
Zolotov S.Yu., Ippolitov I.I., and Loginov S.V. Forecasting Estimates of Surface Air Temperature Changes by the Wavelet Transformation Method. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 331–337.
Eliseev A.A., Rumyantsev D.V., Frolkis V.A. To verification of possible direct measurement of radiative flux in the atmosphere. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 476-481 [in Russian].
Eliseev A.A., Rumyantsev D.V., and Frol’kis V.A. Substantiation of the Possibility of Direct Measurements of Radiative Heat Influx in the Atmosphere. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 359–364.
Krekov G.M., Krekova M.M., Sukhanov A.Ya. Broadband lidar potentiality estimate for remote sensing of the molecular atmosphere. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 482-493 [in Russian].
Ugolnikov O.S., Maslov I.A. Earth's atmosphere remote sensing based on observations of the lunar eclipses. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 494-498 [in Russian].
Ugolnikov O.S. and Maslov I.A. Remote Sensing of the Earth’s Atmosphere Based on Lunar Eclipse Observations. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 365–369.
Lukin V.P., Grigorjev V.M., Antoshkin L.V., Botygina N.N., Emaleev O.N., Konyaev P.A., Kovadlo P.G., Nosov V.V., Skomorovskii V.I., Torgaev A.V. Possibilities of using adaptive optics in solar telescopes. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 499-511 [in Russian].
Lukin V.P., Grigor’ev V.M., Antoshkin L.V., Botygina N.N., Emaleev O.N., Konyaev P.A., Kovadlo P.G., Nosov V.V., Skomorovskii V.I., and Torgaev A.V. Applicability of Adaptive Optics for Solar Telescopes. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 370–382.
Volkov S.N. The photoelectric photon counter module with a galvanic decoupling for laser sounding of the atmosphere. // Optika Atmosfery i Okeana. 2009. V. 22. No. 05. P. 512-515 [in Russian].
Volkov S.N. Photoelectron System in the Photon Counting Mode with a Galvanic Decoupler for Laser Sensing of the Atmosphere. // Atmospheric and Oceanic Optics, 2009, V. 22. No. 03. pp. 383–386.

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