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Integrated Studies of Tropospheric Aerosol at the Institute of Atmospheric Optics (Development Stages)

Atmospheric and Oceanic Optics volume 33pages 27–41 (2020)Cite this article

Abstract

In the work dedicated to the 50th anniversary of the V.E. Zuev Institute of Atmospheric Optics, Siberian Branch, Russian Academy of Sciences (IAO SB RAS), experimental studies are reviewed in a certain chronology that have been milestones in the development of an integrated study of aerosol life in the atmosphere. We discuss briefly the main results from the series of expedition studies of the optical and microphysical properties of aerosol of marine coastal hazes, arid zones, and different geographic regions of the World Ocean. The modern set of methods and instrumentation that we use to measure the aerosol characteristics in the monitoring mode at the network of IAO SB RAS stations is described. The results of multiyear studies of tropospheric aerosol using aircraft laboratories are presented.

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Fig. 1.

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ACKNOWLEDGMENTS

The authors cordially thank the large personnel of the Institute who, over 50 years, at different stages participated in the development of the methodology, creation of instrumentation, and collectively shared successes and numerous difficulties. We should also specially note that an advance could hardly be possible without the close, friendly cooperation with many teams of Russian and foreign scientific organizations. We are deeply indebted to all those who worked with us in expeditions, met at conferences, debated and exchanged ideas, prepared publications, implemented collaborative projects.

Funding

The results discussed in the paper were obtained within the main subject area of IAO SB RAS and, in different years, were supported by grants from the Russian Fund for Basic Research, the Federal Target Program, and programs of the RAS and the SB RAS. Financing received in 2019 as part of the Russian Science Foundation (RSF) project (agreement no. 19-77-20 092) “Conducting research on the basis of the existing world-level scientific infrastructure” will undoubtedly favor the development of the study of such a unique object as atmospheric aerosol.

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  1. V.E. Zuev Institute of Atmospheric Optics, Siberian Branch, Russian Academy of Sciences, 634055, Tomsk, Russia

    M. V. Panchenko, Yu. A. Pkhalagov, B. D. Belan, V. S. Kozlov, S. M. Sakerin, D. M. Kabanov, V. N. Uzhegov, N. N. Shchelkanov, V. V. Polkin, S. A. Terpugova, G. N. Tolmachev, E. P. Yausheva, M. Yu. Arshinov, D. V. Simonenkov, V. P. Shmargunov, D. G. Chernov, Yu. S. Turchinovich, Vas. V. Pol’kin, T. B. Zhuravleva, I. M. Nasrtdinov & P. N. Zenkova

  2. Institute of Monitoring Climatic and Ecological Systems, Siberian Branch, Russian Academy of Sciences, 634055, Tomsk, Russia

    M. V. Kabanov

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  1. M. V. Panchenko
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  2. M. V. Kabanov
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  12. G. N. Tolmachev
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  14. M. Yu. Arshinov
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Correspondence to M. V. Panchenko.

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Translated by O. Bazhenov

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Panchenko, M.V., Kabanov, M.V., Pkhalagov, Y.A. et al. Integrated Studies of Tropospheric Aerosol at the Institute of Atmospheric Optics (Development Stages). Atmos Ocean Opt 33, 27–41 (2020). https://doi.org/10.1134/S1024856020010108

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Keywords:

  • aerosol
  • optical and microphysical characteristics
  • scattering
  • extinction
  • and absorption coefficients
  • spectral transparency
  • aerosol optical depth