Regional Features of the Buoyancy Frequency Distribution in the Laptev and East Siberian Seas
A. A. Bukatov, E. A. Pavlenko✉, N. M. Solovei
Marine Hydrophysical Institute, Russian Academy of Sciences, Sevastopol, Russian Federation
✉ e-mail: mhi.pavlenko@gmail.com
Abstract
Purpose. The aim of the paper is to study buoyancy frequency in the Laptev and East Siberian Seas and to assess correlation relations between the intra-year variability of the Väisäl – Brent frequency maximum and the climatic indices reflecting the atmosphere and hydrosphere state.
Methods and Results. Based on the World Ocean Atlas 2013 for 1955–2012, the features of spatial and temporal variability of the buoyancy frequency distribution and its maximum depth in the Laptev and East Siberian seas are considered. It is found that the highest values of the Väisäl – Brent frequency are observed in the estuaries of the rivers Lena, Khatanga, Kolyma and Indigirka in summer where they attain 70–86 cycle/hour. In the deep-water northern areas of the seas under study, the majority of the water area is covered with ice throughout the whole year. As a consequence the surface layer of water is heated slightly and stability of stratification is much lower. The buoyancy frequency values in the seasonal pycnocline attain 24–46 cycle/hour. As a result of advection of the transformed Pacific waters in the northern and southeastern regions of the East Siberian Sea, on the depths 25–55 m observed is the layer of constant pycnocline where the Väisäl – Brent frequency values can mount to 21 cycles/hour. Correlation analysis is carried out for the relations between the intra-annual variability of the Väisäl – Brent frequency maximum and the climatic indices (North Atlantic Oscillation, Arctic Oscillation, Pacific Decadal Oscillation, Gulf Stream North Wall) reflecting the atmosphere and hydrosphere state. It is shown that relationship between the buoyancy frequency maximum and the two latter indices is the most pronounced.
Conclusions. The results of the carried out investigations show that the features of spatial-temporal variability of the buoyancy frequency distribution and its maximum depth in the Laptev and East Siberian seas are conditioned by the river discharge and also by advection in the Arctic region of the Atlantic and transformed Pacific waters inflowing from the adjacent basins.
Keywords
Arctic, Laptev Sea, East Siberian Sea, buoyancy frequency, water stability, water vertical structure
Acknowledgements
The research is carried out within the framework of the state order on theme No. 0827-2019-0003.
Original russian text
Original Russian Text © A. A. Bukatov, E. A. Pavlenko, N. M. Solovei, 2019, published in MORSKOY GIDROFIZICHESKIY ZHURNAL, Vol. 35, Iss. 5, pp. 437–448 (2019)
For citation
Bukatov, A.A., Pavlenko, E.A. and Solovei, N.M., 2019. Regional Features of the Buoyancy Frequency Distribution in the Laptev and East Siberian Seas. Physical Oceanography, 26(5), pp. 387-396. doi:10.22449/1573-160X-2019-5-387-396
DOI
10.22449/1573-160X-2019-5-387-396
References
- Matishov, G.G., 2008. The Influence of Climatic and Ice Regime Variability on Navigation. Herald of the Russian Academy of Sciences, [e-journal] 78(5), pp. 457-463. https://doi.org/10.1134/S1019331608050043
- Danilov, A.I., Alekseev, G.V. and Klepikov, A.V., 2014. The Consequences of Climate Change for Maritime Activity in the Arctic. Ice and Snow, 54(3), pp. 91-99. https://doi.org/10.15356/2076-6734-2014-3-91-99 (in Russian).
- Borodachev, V.E. and Borodachev, I.V., 2016. Laptev Sea Ice Extent in Arctic Climate Fluctuation Conditions. Arctic and Antarctic Research, (3), pp. 60-73 (in Russian).
- Bukatov, A.E., Bukatov, A.A. and Babiy, M.V., 2017. Spatial and Temporal Variability of the Arctic Sea Ice Distribution. Kriosfera Zemli, XXI(1), pp. 85-92. doi:10.21782/ KZ1560-7496-2017-1(85-92) (in Russian).
- Bukatov, A.E., Pavlenko, E.A. and Solovei, N.M., 2017. [Variability of the Buoyancy Frequency Vertical Structure in the Arctic Seas of Russia]. In: S. O. Papkov, ed., 2017. Applied Problems of Mathematics: Materials of XХV International Scientific and Technical Conference (Sebastopol, September 18-22, 2017). Sevastopol: SevSU, pp. 65-67 (in Russian).
- Bukatov, A.E. and Pavlenko, E.A., 2017. The Spatial and Temporal Variability of Distribution of the Buoyancy Frequency in the Chukchi Sea. Processes in GeoMedia, (3), pp. 573-579 (in Russian).
- Golubeva, E.N., 2017. Numerical Modeling of the East-Siberian Sea Hydrology. In: SSUGT, 2017. Interexpo GEO-Siberia-2017. XIII International Scientific Congress: International Scientific Conference "Remote Sensing Methods of the Earth and Photogrammetry, Environmental Monitoring, Geoecology". Novosibirsk: SSUGT. Vol. 1, pp. 121-125 (in Russian).
- Timokhov, L.A., Frolov, I.E., Kassens, H., Karpiy, V.Yu., Lebedev, N.V., Malinovsky, S.Yu., Polyakov, I.V. and Hoelemann, J., 2016. Changes of Termohaline Characteristics of Transpolar System of the Arctic Ocean. Arctic and Antarctic Research, (2), pp. 34-49 (in Russian).
- Yurasov, G.I., 2000. [Oceanographic Characteristics of the Waters of the South-Eastern Part of the Laptev Sea and the Western Part (Dmitry Laptev Strait) of the East-Siberian Sea in September 1999]. In: I. P. Semiletov, ed., 2000. Proceedings of the Arctic Regional Centre. Vol. 2, part 1: Hydrometeorological and Biogeochemical Research in the Arctic. Vladivostok, pp. 63–68 (in Russian).
- Bukatov, A.A., Pavlenko, E.A. and Solovei, N.M., 2018. [Spatio-Temporal Variability of the Buoyancy Frequency Distribution in the Laptev Sea and the East Siberian Sea]. In: MHI, 2018. The Seas of Russia: Seas of Russia: Methods, Means and Results of Research. Abstract Book of the All-Russian Scientific Conference (Sevastopol, 24-28 September, 2018). Sevastopol: MHI RAS, pp. 215-216 (in Russian).
- Monin, A.S., Neyman, V.G. and Filyushkin, B.N., 1970. [Density Stratification in Ocean]. Doklady Akademii Nauk SSSR, 191(6), pp. 1277-1279 (in Russian).
- Sherstyankin, P.P. and Kuimova, L.N., 2009. Vertical Stability and the Brunt-Väisäla Frequency of Deep Natural Waters by the Example of Lake Baikal, Lake Tanganyika, and the World Ocean. Doklady Earth Sciences, [e-journal] 429(2), pp. 1553-1558. https://doi.org/10.1134/S1028334X09090293
- Locarnini, R.A., Mishonov, A.V., Antonov, J.I., Boyer, T.P., Garcia, H.E., Baranova, O.K., Zweng, M.M., Paver, C.R., Reagan, J.R., Johnson, D.R., Hamilton, M. and Seidov, D., 2013. World Ocean Atlas 2013, Volume 1: Temperature. NOAA Atlas NESDIS 73, 40 p.
- Zweng, M.M., Reagan, J.R., Antonov, J.I., Locarnini, R.A., Mishonov, A.V., Boyer, T.P., Garcia, H.E., Baranova, O.K., Johnson, D.R., Seidov, D., Biddle, M.M., 2013. World Ocean Atlas 2013, Volume 2: Salinity. NOAA Atlas NESDIS 74, 39 p.
- Bukatov, A.E. and Solovei, N.M., 2017. Evaluation of the Density Field Vertical Structure and the Characteristics of Internal Waves Relation with Large-Scale Atmospheric Circulation in the Peruvian and Benguela Upwelling Areas. Processes in GeoMedia, (2), pp. 485-490 (in Russian).
- Bloshkina, E.V., Makhotin, M.S., Volkov, D.L. and Koldunov, N.V., 2016. Comparison the Arctic Ocean the Thermohaline Characteristics Distribution from the Observed Data and MITgcm Model Simulated Data. Proceedings of the Russian State Hydrometeorological University, (43), pp. 67-88.
- Makhotin, M.S. and Dmitrenko, I.A., 2011. Interannual Variability of Pacific Summer Waters in the Arctic Ocean. Doklady Earth Sciences, [e-journal] 438(1), pp. 730-732. https://doi.org/10.1134/S1028334X11050345
- Morozov, E.G. and Pisarev, S.V., 2004. Internal Waves and Polynya Formation in the Laptev Sea. Doklady Earth Sciences, [e-journal] 398(7), pp. 983-986.