MODELING SPRING HYDRODYNAMIC REGIME OF SURFACE WATERS IN KAMCHATKA STRAIT
Аннотация и ключевые слова
Аннотация (русский):
On the basis of numerical modeling, an analysis of the average multiyear pattern of the spring circulation of surface waters in the Kamchatka Strait is performed. It was revealed that in the spring period the winter regime of water circulation continues here, however, the transition to the summer circulation mode begins and the influx of warm Pacific water masses to the Bering Sea is intensifying. The results obtained are somewhat different from the generally accepted ones.

Ключевые слова:
Aleutian Island Arc, Kamchatka Strait, Kamchatka Current, winter and summer monsoons, water circulation
Список литературы

1. Arsenyev, V. S. (1967) , Flows and Water Masses of the Bering Sea, 135 pp., Science, Moscow (in Russian).

2. Cokelet, E. D., M. L. Schall, D. M. Dougherty (1996) , ADCP-referenced geostrophic circulation in the Bering Sea Basin, Physical Oceanography, 26, p. 1113-1128, https://doi.org/10.1175/1520-0485(1996)026<1113:ARGCIT>2.0.CO;2.

3. Dobrovolsky, A. D., V. S. Arsenyev (1961) , The Hydrological Characteristic of the Bering Sea, Trudy IO AS USSR, 38, p. 64-96 (in Russian).

4. Felsenbaum, A. I. (1956) , The method of total flows in the classical theory of sea currents, Trudy IO AS USSR, 19, p. 57-82 (in Russian).

5. Felsenbaum, A. I. (1970) , Dynamics of sea currents , Results of Science. Hydromechanics, p. 97-338, VINITI, Moscow (in Russian, http://www.esrl. noaa.gov/psd/data/gridded/data.ncep.reanalysis.deri ved.html).

6. Khen, G. V. (1989) , Oceanographic conditions and Bering Sea biological productivity, Proceedings of the International Symposium: On the Biology and Management of Walleye Pollock, p. 31-52, University of Alaska Sea Grant. AK-SG-89-01, Fairbanks.

7. Khen, G. V., E. O. Basyuk (2005) , Oceanographic Conditions of the Bering Sea in BASIS, NPAFC Technological Report, no. 6, p. 21-23.

8. Khen, G. V., E. O. Basyuk, V.I. Matveev, N. S. Vanin (2013) , Hydrography and biological resources in the western Bering Sea, Deep Sea Resource II, 94, p. 106-120, https://doi.org/10.1016/j.dsr2.2013.03.034.

9. Khen, G. V., A. V. Zavolokin (2015) , Change in water circulation and its importance in the distribution and abundance of salmon in the western part of the Bering Sea at the beginning of the 21st century, Izvestia of TINRO, 181, p. 95-114, https://doi.org/10.1134/S1063074015070032 (in Russian).

10. Khen, G. V., A. N. Zaochniy (2009) , The variability of the flow of the Kamchatka current and oceanological parameters in the Kamchatka Strait, Izvestia of TINRO, 158, p. 247-260 (in Russian).

11. Luchin, V. A. (2008) , Thermal regime of the waters of the Far Eastern seas (Japan, The sea of Okhotsk, Bering), The dissertation of the Dr. Geogr. Sciences, Il'ichev Pacific Oceanological Institute, FEBRAS, Vladivostok (in Russian).

12. Overland, J. E., M. C. Spillane, H. E. Hurlburt, A. J. Wallcraft (1994) , A numerical study of the circulation of the Bering Sea basin and exchange with the North Pacific Ocean, Physical Oceanography, 24, p. 736-758, https://doi.org/10.1175/1520-0485(1994)024<0736:ANSOTC>2.0.CO;2.

13. Polyakova, A. M., G. A. Vlasova, A. S. Vasilyev (2002) , The Influence of the Atmosphere on the Underlying Surface and Hydrodynamic Processes of the Bering Sea, 202 pp., Dal'nauka, Vladivostok (in Russian).

14. Prants, S. V., A. G. Andreev, M. Y. Uleysky, M. V. Budyansky (2014) , Lagrangian study of temporal changes of a surface flow through the Kamchatka Strait, Ocean Dynamics, 64, p. 771-780, https://doi.org/10.1007/s10236-014-0706-9.

15. Reed, R. K. (1995) , On geostrophic reference levels in the Bering Sea Basin, Physical Oceanography, 51, p. 489-498, https://doi.org/10.1007/BF02286394.

16. Rogachev, K. A., N. V. Shlyk (2008) , Disintegration of the Alaskan Current into Aleutian vortices and Temperature Rise in the Western Sub-Arctic of the Pacific Ocean, Bulletin of the Far East Branch RAS, no. 6, p. 99-102 (in Russian).

17. Rogachev, K. A., N. V. Shlyk (2010) , Increase in the radius of Aleutian vortices and their long-term evolution, Meteorology and Hydrology, no. 3, p. 68-73, https://doi.org/10.3103/S1068373910030076 (in Russian).

18. Schlitzer, R. (2002) , Interactive analysis and visualization of geoscience data with Ocean Data View, Computers & Geosciences, 28, p. 1211-1218, https://doi.org/10.1016/S0098-3004(02)00040-7.

19. Shapiro, N. B. (1965) , Analytical study of the relationship between wind and current in the equatorial ocean zone, Doklady AS USSR, 164, no. 2, p. 319-322 (in Russian).

20. Solomon, H., K. Ahlnas (1978) , Eddies in the Kamchatka Current, Deep Sea Resource, 25, p. 403-410, https://doi.org/10.1016/0146-6291(78)90566-0.

21. Stabeno, P. J., R. K. Reed (1994) , Circulation in the Bering Sea basin by satellite tracked drifters, Physical Oceanography, 24, p. 848-854, https://doi.org/10.1175/1520-0485(1994)024<0848:CITBSB>2.0.CO;2.

22. Stabeno, P. J., J. D. Schumacher, R. Ohtani (1999) , The physical oceanography of the Bering Sea, Proceedings of the International Symposium: Dynamics of the Bering Sea, p. 1-28, University of Alaska Sea Grant College Programm, Fairbanks.

23. Shtokman, V. B. (1954) , About the cause of circular currents near the islands and opposite currents near the coast of the straits, Izvestiya AS USSR. Ser. Geogr., no. 4, p. 29-37 (in Russian).

24. Takenouti, A. Y., R. Ohtani (1974) , Currents and water masses in the Bering Sea: A review of Japanese work, Oceanography of the Bering Sea: with emphasis on renewable resources, p. 39-57, Institute of Marine Science University of Alaska, Fairbanks.

25. Timonov, V. V. (1960) , Resulting and secondary currents in the seas with tides, Trudy of the Oceanographic Commission AS USSR, 10, no. 1, p. 43-50 (in Russian).

26. Vasiliev, A. S. (2001) , Adaptive Learning System of Forecasting Classes of Natural Processes. Part 1, 136 pp., Gidrometeoizdat, St. Petersburg (in Russian).

27. Vlasova, G. A., A. S. Vasiliev, G. V. Shevchenko (2008) , Spatio-Temporal Variability of the Structure and Dynamics of the Waters of the Sea of Okhotsk, 359 pp., Nauka, Moscow (in Russian).

28. Vlasova, G. A., M. N. Demenok, Ba Xuan Nguyen, Hong Long Buy (2016a) , The role of atmospheric circulation in the spatial-temporal variability of the structure of currents in the western part of the South China Sea, Izvestiya RAN. FAO, 52, no. 3, p. 361-372, https://doi.org/10.1134/S0001433816030130 (in Russian).

29. Vlasova, G. A., Ba Xuan Nguyen, M. N. Demenok (2016b) , Water Circulation of the South China Sea in the Vietnamese Current Zone under the Conditions of the Southern Tropical Cyclone in the Spring of 1999: Results of Numerical Simulation, Fundamental'naya i Prikladnaya Gidrofizika, 9, no. 4, p. 25-34 (in Russian).

30. Wang, J., H. S. Hu, K. Mizobata, S. Saitoh (2009) , Seasonal variations of sea ice and ocean circulation in the Bering Sea: A model-data fusion study, Geophysical. Resource, 114, p. C02011, https://doi.org/10.1029/2008JC004727.

31. Zhabin, I. A., V. B. Lobanov, S. Watanabe, M. Vakita, S. N. Taranova (2010) , Water exchange between the Bering Sea and the Pacific Ocean through the Kamchatka Strait, Meteorology and Hydrology, no. 3, p. 84-92, https://doi.org/10.3103/S106837391003009X (in Russian).

32. Zhabin, I. A., E. V. Dmitrieva, N. S. Vanin (2017) , Impact of wind and ice conditions on upwelling off the west coast of the Kamchatka Peninsula (Sea of Okhotsk) according to satellite observations, Izvestiya - Atmospheric and Oceanic Physics, no. 3, p. 22-29 (in Russian).

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