Integrated airborne investigation of the air composition over the Russian Sector of the Arctic

The change of the global climate is most pronounced in the Arctic, where the air temperature increases two to three times faster than the global average. This process is associated with an increase in the concentration of greenhouse gases in the atmosphere. There are publications predicting the shar...

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Main Authors: Belan, Boris D., Ancellet, Gerard, Andreeva, Irina S., Antokhin, Pavel N., Arshinova, Viktoria G., Arshinov, Mikhail Y., Balin, Yurii S., Barsuk, Vladimir E., Belan, Sergei B., Chernov, Dmitry G., Davydov, Denis K., Fofonov, Alexander V., Ivlev, Georgii A., Kotel’nikov, Sergei N., Kozlov, Alexander S., Kozlov, Artem V., Law, Katharine, Mikhal’chishin, Andrey V., Moseikin, Igor A., Nasonov, Sergei V., Nédélec, Philippe, Okhlopkova, Olesya V., Ol’kin, Sergei E., Panchenko, Mikhail V., Paris, Jean-Daniel, Penner, Iogannes E., Ptashnik, Igor V., Rasskazchikova, Tatyana M., Reznikova, Irina K., Romanovskii, Oleg A., Safatov, Alexander S., Savkin, Denis E., Simonenkov, Denis V., Sklyadneva, Tatyana K., Tolmachev, Gennadii N., Yakovlev, Semyon V., Zenkova, Polina N.
Format: Text
Language:English
Published: 2022
Subjects:
Arctic
Barents Sea
Kara Sea
black carbon
Chukchi
permafrost
Online Access:https://doi.org/10.5194/amt-2021-437
https://amt.copernicus.org/preprints/amt-2021-437/
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record_format openpolar
spelling ftcopernicus:oai:publications.copernicus.org:amtd100542 2023-05-15T14:50:59+02:00 Integrated airborne investigation of the air composition over the Russian Sector of the Arctic Belan, Boris D. Ancellet, Gerard Andreeva, Irina S. Antokhin, Pavel N. Arshinova, Viktoria G. Arshinov, Mikhail Y. Balin, Yurii S. Barsuk, Vladimir E. Belan, Sergei B. Chernov, Dmitry G. Davydov, Denis K. Fofonov, Alexander V. Ivlev, Georgii A. Kotel’nikov, Sergei N. Kozlov, Alexander S. Kozlov, Artem V. Law, Katharine Mikhal’chishin, Andrey V. Moseikin, Igor A. Nasonov, Sergei V. Nédélec, Philippe Okhlopkova, Olesya V. Ol’kin, Sergei E. Panchenko, Mikhail V. Paris, Jean-Daniel Penner, Iogannes E. Ptashnik, Igor V. Rasskazchikova, Tatyana M. Reznikova, Irina K. Romanovskii, Oleg A. Safatov, Alexander S. Savkin, Denis E. Simonenkov, Denis V. Sklyadneva, Tatyana K. Tolmachev, Gennadii N. Yakovlev, Semyon V. Zenkova, Polina N. 2022-02-15 application/pdf https://doi.org/10.5194/amt-2021-437 https://amt.copernicus.org/preprints/amt-2021-437/ eng eng doi:10.5194/amt-2021-437 https://amt.copernicus.org/preprints/amt-2021-437/ eISSN: 1867-8548 Text 2022 ftcopernicus https://doi.org/10.5194/amt-2021-437 2022-02-21T17:22:16Z The change of the global climate is most pronounced in the Arctic, where the air temperature increases two to three times faster than the global average. This process is associated with an increase in the concentration of greenhouse gases in the atmosphere. There are publications predicting the sharp increase of methane emissions into the atmosphere due to permafrost thawing. Therefore, it is important to study how the air composition in the Arctic changes in the changing climate. In the Russian sector of the Arctic, the air composition was measured only in the surface atmospheric layer at the coastal stations or earlier at the drifting stations. Vertical distributions of gas constituents of the atmosphere and aerosol were determined only in few small regions. That is why the integrated experiment was carried out to measure the composition of the troposphere in the entire Russian sector of the Arctic from onboard the Optik Tu-134 aircraft laboratory in the period of September 4 to 17 of 2020. The aircraft laboratory was equipped with contact and remote measurement facilities. The contact facilities were capable of measuring the concentrations of CO 2 , CH 4 , O 3 , CO, NO X , and SO 2 , as well as the disperse composition of particles in the size range from 3 nm to 32 µm, black carbon, organic and inorganic components of atmospheric aerosol. The remote facilities were operated to measure the water transparency in the upper layer of the ocean, the chlorophyll content in water, and spectral characteristics of the underlying surface. The measured data have shown that the ocean continues absorbing СО 2 . This process is most intense over the Barents and Kara Seas. The recorded methane concentration was increased over all the arctic seas, reaching 2090 ppb in the near-water layer over the Kara Sea. The contents of other gas components and black carbon were close to the background level. In bioaerosol, bacteria predominated among the identified microorganisms. In most samples, they were represented by coccal forms, less often spore-forming and non-spore-bearing rod-shaped bacteria. No dependence of the representation of various bacterial genera on the height and the sampling site was revealed. The most turbid during the experiment was the upper layer of the Chukchi and Bering Seas. The Barents Sea turned out to be the most transparent. The differences in extinction varied more than 1.5 times. In all measurements, except for the Barents Sea, the tendency to an increase in chlorophyll fluorescence in more transparent waters was observed. Text Arctic Barents Sea black carbon Chukchi Kara Sea permafrost Copernicus Publications: E-Journals Arctic Barents Sea Kara Sea
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description The change of the global climate is most pronounced in the Arctic, where the air temperature increases two to three times faster than the global average. This process is associated with an increase in the concentration of greenhouse gases in the atmosphere. There are publications predicting the sharp increase of methane emissions into the atmosphere due to permafrost thawing. Therefore, it is important to study how the air composition in the Arctic changes in the changing climate. In the Russian sector of the Arctic, the air composition was measured only in the surface atmospheric layer at the coastal stations or earlier at the drifting stations. Vertical distributions of gas constituents of the atmosphere and aerosol were determined only in few small regions. That is why the integrated experiment was carried out to measure the composition of the troposphere in the entire Russian sector of the Arctic from onboard the Optik Tu-134 aircraft laboratory in the period of September 4 to 17 of 2020. The aircraft laboratory was equipped with contact and remote measurement facilities. The contact facilities were capable of measuring the concentrations of CO 2 , CH 4 , O 3 , CO, NO X , and SO 2 , as well as the disperse composition of particles in the size range from 3 nm to 32 µm, black carbon, organic and inorganic components of atmospheric aerosol. The remote facilities were operated to measure the water transparency in the upper layer of the ocean, the chlorophyll content in water, and spectral characteristics of the underlying surface. The measured data have shown that the ocean continues absorbing СО 2 . This process is most intense over the Barents and Kara Seas. The recorded methane concentration was increased over all the arctic seas, reaching 2090 ppb in the near-water layer over the Kara Sea. The contents of other gas components and black carbon were close to the background level. In bioaerosol, bacteria predominated among the identified microorganisms. In most samples, they were represented by coccal forms, less often spore-forming and non-spore-bearing rod-shaped bacteria. No dependence of the representation of various bacterial genera on the height and the sampling site was revealed. The most turbid during the experiment was the upper layer of the Chukchi and Bering Seas. The Barents Sea turned out to be the most transparent. The differences in extinction varied more than 1.5 times. In all measurements, except for the Barents Sea, the tendency to an increase in chlorophyll fluorescence in more transparent waters was observed.
format Text
author Belan, Boris D.
Ancellet, Gerard
Andreeva, Irina S.
Antokhin, Pavel N.
Arshinova, Viktoria G.
Arshinov, Mikhail Y.
Balin, Yurii S.
Barsuk, Vladimir E.
Belan, Sergei B.
Chernov, Dmitry G.
Davydov, Denis K.
Fofonov, Alexander V.
Ivlev, Georgii A.
Kotel’nikov, Sergei N.
Kozlov, Alexander S.
Kozlov, Artem V.
Law, Katharine
Mikhal’chishin, Andrey V.
Moseikin, Igor A.
Nasonov, Sergei V.
Nédélec, Philippe
Okhlopkova, Olesya V.
Ol’kin, Sergei E.
Panchenko, Mikhail V.
Paris, Jean-Daniel
Penner, Iogannes E.
Ptashnik, Igor V.
Rasskazchikova, Tatyana M.
Reznikova, Irina K.
Romanovskii, Oleg A.
Safatov, Alexander S.
Savkin, Denis E.
Simonenkov, Denis V.
Sklyadneva, Tatyana K.
Tolmachev, Gennadii N.
Yakovlev, Semyon V.
Zenkova, Polina N.
spellingShingle Belan, Boris D.
Ancellet, Gerard
Andreeva, Irina S.
Antokhin, Pavel N.
Arshinova, Viktoria G.
Arshinov, Mikhail Y.
Balin, Yurii S.
Barsuk, Vladimir E.
Belan, Sergei B.
Chernov, Dmitry G.
Davydov, Denis K.
Fofonov, Alexander V.
Ivlev, Georgii A.
Kotel’nikov, Sergei N.
Kozlov, Alexander S.
Kozlov, Artem V.
Law, Katharine
Mikhal’chishin, Andrey V.
Moseikin, Igor A.
Nasonov, Sergei V.
Nédélec, Philippe
Okhlopkova, Olesya V.
Ol’kin, Sergei E.
Panchenko, Mikhail V.
Paris, Jean-Daniel
Penner, Iogannes E.
Ptashnik, Igor V.
Rasskazchikova, Tatyana M.
Reznikova, Irina K.
Romanovskii, Oleg A.
Safatov, Alexander S.
Savkin, Denis E.
Simonenkov, Denis V.
Sklyadneva, Tatyana K.
Tolmachev, Gennadii N.
Yakovlev, Semyon V.
Zenkova, Polina N.
Integrated airborne investigation of the air composition over the Russian Sector of the Arctic
author_facet Belan, Boris D.
Ancellet, Gerard
Andreeva, Irina S.
Antokhin, Pavel N.
Arshinova, Viktoria G.
Arshinov, Mikhail Y.
Balin, Yurii S.
Barsuk, Vladimir E.
Belan, Sergei B.
Chernov, Dmitry G.
Davydov, Denis K.
Fofonov, Alexander V.
Ivlev, Georgii A.
Kotel’nikov, Sergei N.
Kozlov, Alexander S.
Kozlov, Artem V.
Law, Katharine
Mikhal’chishin, Andrey V.
Moseikin, Igor A.
Nasonov, Sergei V.
Nédélec, Philippe
Okhlopkova, Olesya V.
Ol’kin, Sergei E.
Panchenko, Mikhail V.
Paris, Jean-Daniel
Penner, Iogannes E.
Ptashnik, Igor V.
Rasskazchikova, Tatyana M.
Reznikova, Irina K.
Romanovskii, Oleg A.
Safatov, Alexander S.
Savkin, Denis E.
Simonenkov, Denis V.
Sklyadneva, Tatyana K.
Tolmachev, Gennadii N.
Yakovlev, Semyon V.
Zenkova, Polina N.
author_sort Belan, Boris D.
title Integrated airborne investigation of the air composition over the Russian Sector of the Arctic
title_short Integrated airborne investigation of the air composition over the Russian Sector of the Arctic
title_full Integrated airborne investigation of the air composition over the Russian Sector of the Arctic
title_fullStr Integrated airborne investigation of the air composition over the Russian Sector of the Arctic
title_full_unstemmed Integrated airborne investigation of the air composition over the Russian Sector of the Arctic
title_sort integrated airborne investigation of the air composition over the russian sector of the arctic
publishDate 2022
url https://doi.org/10.5194/amt-2021-437
https://amt.copernicus.org/preprints/amt-2021-437/
geographic Arctic
Barents Sea
Kara Sea
geographic_facet Arctic
Barents Sea
Kara Sea
genre Arctic
Barents Sea
black carbon
Chukchi
Kara Sea
permafrost
genre_facet Arctic
Barents Sea
black carbon
Chukchi
Kara Sea
permafrost
op_source eISSN: 1867-8548
op_relation doi:10.5194/amt-2021-437
https://amt.copernicus.org/preprints/amt-2021-437/
op_doi https://doi.org/10.5194/amt-2021-437
_version_ 1766322039061217280

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