Abstract
In this paper, we use the unstructured grid model SCHISM to simulate the thermohydrodynamics in a chain of baroclinic, interconnected basins. The model shows a good skill in simulating the horizontal circulation and vertical profiles of temperature, salinity, and currents. The magnitude and phases of the seasonal changes of circulation are consistent with earlier observations. Among the mesoscale and subbasin-scale circulation features that are realistically simulated are the anticyclonic coastal eddies, the Sebastopol and Batumi eddies, the Marmara Sea outflow around the southern coast of the Limnos Island, and the pathway of the cold water originating from the shelf. The superiority of the simulations compared to earlier numerical studies is demonstrated with the example of model capabilities to resolve the strait dynamics, gravity currents originating from the straits, high-salinity bottom layer on the shallow shelf, as well as the multiple intrusions from the Bosporus Strait down to 700 m depth. The warm temperature intrusions from the strait produce the warm water mass in the intermediate layers of the Black Sea. One novel result is that the seasonal intensification of circulation affects the interbasin exchange, thus allowing us to formulate the concept of circulation-controlled interbasin exchange. To the best of our knowledge, the present numerical simulations, for the first time, suggest that the sea level in the interior part of the Black Sea can be lower than the sea level in the Marmara Sea and even in some parts of the Aegean Sea. The comparison with observations shows that the timings and magnitude of exchange flows are also realistically simulated, along with the blocking events. The short-term variability of the strait transports is largely controlled by the anomalies of wind. The simulations demonstrate the crucial role of the narrow and shallow strait of Bosporus in separating the two pairs of basins: Aegean-Marmara Seas from one side and Azov-Black Seas from the other side. The straits of Kerch and Dardanelles provide sufficient interbasin connectivity that prevents large phase lags of the sea levels in the neighboring basins. The two-layer flows in the three straits considered here show different dependencies upon the net transport, and the spatial variability of this dependence is also quite pronounced. We show that the blocking of the surface flow can occur at different net transports, thus casting doubt on a previous approach of using simple relationships to prescribe (steady) outflow and inflow. Specific attention is paid to the role of synoptic atmospheric forcing for the basin-wide circulation and redistribution of mass in the Black Sea. An important controlling process is the propagation of coastal waves. One major conclusion from this research is that modeling the individual basins separately could result in large inaccuracies because of the critical importance of the cascading character of these interconnected basins.
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References
Alpar B, Yüce H (1998) Sea-level variations and their interactions between the Black Sea and the Aegean Sea. Estuar Coast Shelf Sci 46:609–619
Altman EN (1991) Dynamics of waters of the Kerch Strait / hydrometeorology and hydrology of the USSR seas. The “Sea of USSR” Project. V.4. The Black Sea.– L.:Hydrometeoizdat, St. Petersburg, pp 291–328
Aydogan B, Ayat B, Ozturk MN, Cevik EO, Yuksel Y (2010) Current velocity forecasting in straits with artificial neural networks, a case study: Strait of Istanbul. Ocean Eng 37(5–6):443–453
Bajo M, Ferrarin C, Dinu I, Umgiesser G, Stanica A (2014) The water circulation near the Danube Delta and the Romanian coast modelled with finite elements. Cont. Shelf Res 78:62–74. doi:10.1016/j.csr.2014.02.006
Beşiktepe ST, Sur Hİ, Özsoy E, Latif MA, Oǧuz T, Ünlüata Ü (1994) The circulation and hydrography of the Marmara Sea. Progress in Oceanography 34(4):285–334
Blokhina MD, Afanasyev YD (2003) Baroclinic instability and transient features of mesoscale surface circulation in the Black Sea: laboratory experiment. J Geophys Res 108(C10):3322. doi:10.1029/2003JC001979
Chiggiato J, Jarosz E, Book JW, Dykes J, Torrisi L, Poulain P-M, Gerin R, Horstmann J, Beşiktepe Ş (2012) Dynamics of the circulation in the Sea of Marmara: numerical modeling experiments and observations from the Turkish straits system experiment. Ocean Dyn 62:139–159
Danilov S (2013) Ocean modeling on unstructured meshes. Ocean Model 69:195–210
Engel M (1974) Hydrodynamisch-numerische Ermittlung von Bewegungsvorg¨angen im Schwarzen Meer. Technical Report XXII. Mitteilungen des Instituts fu¨r Meereskunde der Universita¨t Hamburg, Hamburg 72 pp
Farmer DM, Armi L (1986) Maximal two-layer exchange over a sill and through the combination of a sill and contraction with barotropic flow. J Fluid Mech 164:53–76
Fomin VV, Ivanov VA (2007) Coupled modeling of currents and wind waves in the Kerch Strait. Phys Oceanogr 17(5):253–268
Georgievski G, Stanev EV (2006) Paleoevolution of Euroasian watersheds: water transport through the Bosporus Strait as an indicator of the Lateglacial-Holocene transition. Clim Dyn 26(6):631–644
Gökaşan E, Tur H, Ecevitoğlu B et al (2005) Evidence and implications of massive erosion along the strait of İstanbul (Bosporus). Geo-Mar Lett 25(5):324–342
Gökaşan E, Ergin M, Özyalvaç M, Sur HI, Tur H, Görüm T, Ustaömer T, Batuk FG, Alp H, Birkan H, Türker A, Gezgin E, Özturan M (2008) Factors controlling the morphological evolution of the Çanakkale Strait (Dardanelles, Turkey). Geo-Mar Lett 28:107. doi:10.1007/s00367-007-0094-y
Grayek S, Stanev EV, Kandilarov R (2010) On the response of Black Sea level to external forcing: altimeter data and numerical modelling. Ocean Dyn 60:123–140. doi:10.1007/s10236-009-0249-7
Gregg MC, Özsoy E (1999). Mixing on the Black Sea Shelf North of the Bosphorus. Geophys Res Lett 26:1869–1872
Gregg MC, Özsoy E (2002) Flow, water mass changes, and hydraulic in the Bosporus. Journal of Geophysical Research: Oceans (1978–2012) 107(C3):3016. doi:10.1029/2009JC000485
Gregg MC, Özsoy E, Latif MA (1999) Quasi-steady exchange flow in the Bosporus. Geophys Res Lett 26(1):83–86
Herbaut C, Codron F, Crepon M (1998) Separation of a coastal current at a strait level: case of the Strait of Sicily. J Phys Oceanogr 28:1346–1362
Ilıcak M, Özgökmen TM, Özsoy E, Fischer PF (2009) Non-hydrostatic modeling of exchange flows across complex geometries. Ocean Model 29:159–175
IOC, IHO, BODC (2003) Centenary edition of the GEBCO digital atlas, published on CD-ROM on behalf of the Intergovernmental Oceanographic Commission and the International Hydrographic Organization as part of the general bathymetric chart of the oceans. British Oceanographic Data Centre, Liverpool
Ivanov VA, Shapiro NB (2004) Simulation of currents in the Kerch Strait. In: Ecological Safety of the Coastal and Shelf Zones and Complex Utilization of the Shelf Resources [in Russian], Issue 10, ÉKOSI–Gidrofizika, Sevastopol , pp. 207–232
Ivanov VA, Matishov GG, Kushnir VM, Berdnikov CV, Chepyzhenko AI, Povazhny VV, Stepanyan OV (2014) Kerch strait in autumn, 2011: results of the joint complex research carried out in the expedition of MHI, NAS of Ukraine and SSC RAS (in Russian). Mar Geophys J 44–57
Jarosz E, Teague WJ, Book JW, Beşiktepe Ş (2011) On flow variability in the Bosporus Strait. J Geophys Res 116:C08038. doi:10.1029/2010JC006861
Jarosz E, Teague WJ, Book JW, Beşiktepe ŞT (2012) Observations on the characteristics of the exchange flow in the Dardanelles Strait. J Geophys Res 117:C11012. doi:10.1029/2012JC008348
Jarosz E, Teague WJ, Book JW, Beşiktepe ŞT (2013) Observed volume fluxes and mixing in the Dardanelles Strait. J Geophys Res 118. doi:10.1002/jgrc.20396
Kanarska Y, Maderich V (2008) Modelling of seasonal exchange flows through the Dardanelles Strait. Estuar Coast Shelf Sci 79:449–458. doi:10.1016/j.ecss.2008.04.019
Kara AB, Wallcraft AJ, Hurlburt HE, Stanev EV (2008) Air–sea fluxes and river discharges in the Black Sea with a focus on the Danube and Bosporus. J Mar Syst 74(2008):74–95
Karimova S (2011) Eddy statistics for the Black Sea by visible and infrared remote sensing. Remote sensing of the changing oceans. Springer, Berlin, pp 61–75
Korotaev G, Oğuz T, Nikiforov A, Koblinsky C (2003) Seasonal, interannual and mesoscale variability of the Black Sea upper layer circulation derived from altimeter data. J Geophys Research 108(C4):3122
Korotaev G, Oğuz T, Riser S (2006) Intermediate and deep currents of the Black Sea obtained from autonomous profiling floats. Deep Sea Res Pt II 53:1901–1910
Lermusiaux PFJ, Schröter J, Danilov S, Iskandarani M, Pinardi N, Westerink JJ (2013) Multiscale modeling of coastal, shelf, and global ocean dynamics. Ocean Dyn 63(11–12):1341–1344. doi:10.1007/s10236-013-0655-8
Maderich V, Konstantinov S (2002) Seasonal dynamics of the system sea-strait: Black Sea-Bosporus case study. Estuarine, Coastal and Shelf Sciences 55:183–196
Maderich V, Ilin Y, Lemeshko E (2015) Seasonal and interannual variability of the water exchange in the Turkish Straits System estimated by modelling. Mediterr Mar Sci 16(2):444–459
Matishov G, Matishov D, Gargopa Y, Dashkevich L, Berdnikov S, Kulygin V, Arkhipova O, Chikin A, Shabas I, Baranova O, Smolyar I (2008) Climatic atlas of the Sea of Azov 2008. In: Matishov G, Levitus S (eds) NOAA atlas NESDIS 65. U.S. Government Printing Office, Washington, D.C. 148 pp., CD-ROM
Möller L (1928) Alfred Merz’ hydrographishe untersuchungen in Bosphorus und Dardanellen. Veroff. Inst. Meerskunde Univ., Berlin Neue Folge, A., 18, 284 pp
Oğuz T (2005) Hydraulic adjustment of the Bosporus exchange flow. Geophys Res Letters 32:L06604. doi:10.1029/2005GL022353
Oğuz T, Besiktepe S (1999) Observations on the Rim Current structure, CIW formation and transport in the western Black Sea. Deep Sea Research, I 46:1733–1753
Oğuz T, Sur HI (1989) A two-layer model of water exchange through the Dardanelles Strait. Oceanol Acta 12:23–31
Oğuz T, Özsoy E, Latif M, Sur HI, Ünlüata Ü (1990) Modeling of hydraulically controlled exchange flow in the Bosporus Strait. J Phys Oceanogr 20:945–965
Oğuz T, Aubrey DG, Latun VS, Demirov E, Koveshnikov L, Sur HI, Diacanu V, Besiktepe S, Duman M, Limeburner R, Eremeev V (1994) Mesoscale circulation and thermohaline structure of the Black sea observed during hydro Black’91. Deep Sea Research I 41:603–628
Okay S, Jupinet B, Lericolais G, Cifci G, Morigi C (2011) Morphological and stratigraphic investigation of a Holocene subaqueous shelf fan, north of the İstanbul Strait in the Black Sea. Turkish Journal of Earth Sciences, Scientific and Technical Research Council of Turkey 2011(20):287–305
Özsoy E, Unluata U, Top Z (1993) The evolution of Mediterranean water in the Black Sea: interior mixing and material transport by double diffusive intrusions. Prog Oceanogr 31(3):275–320
Özsoy, E., M.A. Latif, H.İ. Sur, Y. Goryachkin (1996) A review of the exchange flow regimes and mixing in the Bosporus Strait. In: F. Briand (ed.), Mediterranean tributary seas, Bull. Inst. Oceanogr. Monaco, Spec. No. CIESM Sci. Ser. 2, Monaco
Özsoy E, Latif MA, Beşiktepe ST, Cetin N, Gregg MC, Belokopytov V, Goryachkin Y, Diaconu V (1998) The Bosporus Strait: exchange fluxes, currents, and sea-level changes. In: Ivanov L, Oğuz T (eds) Ecosystem modeling as a management tool for the Black Sea, NATO Sci. Ser, vol vol. 2. Kluwer Acad, Dordrecht, pp 1–27
Özsoy E, Iorio DD, Gregg M, Backhaus J (2001) Mixing in the Bosporus Strait and the Black Sea continental shelf: observations and a model of the dense water outflow. J. Mar. Sys. 31:99–135
Özsoy, E., M. A. Latif, Ş. Beşiktepe (2002). The current system of the Bosporus Strait based on recent measurements. The 2nd Meeting on the Physical Oceanography of Sea Straits, Villef ranche, 15th–19th April 2002, pp. 177–180
Peneva E, Stanev E, Belokopytov V, Le Traon P-Y (2001) Water transport in the Bosporus Strait estimated from hydro-meteorological and altimeter data: seasonal to decadal variability. J. Mar. Sys. 31:21–33
Ryabtsev YuN (2005) Modeling of hydrophysical processes of the Kerch Strait. In: Ecological safety of coastal and shelf zones and complex use of the shelf resources, Marine Hydrophysical Institute, Sevastopol, Ukraine, 12, 342–352
Sannino G, Sözer A, Özsoy E (2017) A high-resolution modelling study of the Turkish Straits System. Ocean Dyn 67(3):397–432
Scholz P, Lohmann G, Wang Q, Danilov S (2013) Evaluation of a Finite-Element Sea-Ice ocean model (FESOM) setup to study the interannual to decadal variability in the deep-water formation rates. Ocean Dyn 63(4):347–370
Simeonov, J., E. V. Stanev, J. Backhaus, J. Jungclaus, and V. Roussenov (1997) Heat and salt intrusions in the pycnocline from sinking plumes. Test case for the entrainment in the Black Sea. In E. E. and A. Mikaelyan (eds.), Sensitivity to change: Black Sea, Baltic Sea and North Sea, NATO ASI series, Vol. 27, Kluwer Academic, Dordrecht, 417–438.
Sözer A, Özsoy E (2017) Modeling of the Bosporus exchange flow dynamics. Ocean Dyn. doi:10.1007/s10236-016-1026-z
Stanev EV (1990) On the mechanisms of the Black Sea circulation. Earth-Science Rev 28:285–319
Stanev EV (2005) Understanding Black Sea dynamics: overview of recent numerical modelling. Oceanography 18(2):52–71
Stanev EV, Beckers JM (1999) Barotropic and baroclinic oscillations in strongly stratified ocean basins. Numerical study for the Black Sea. J. Mar. Sys. 19:65–112
Stanev EV, Lu X (2013) European semi-enclosed seas: basic physical processes and their numerical modelling. In: Soomere T, Quak E (eds) Preventive methods for coastal protection. Springer, Switzerland, pp 131–179. doi:10.1007/978-3-319-00440-2_5
Stanev EV, Peneva EL (2002) Regional sea level response to global climatic change: Black Sea examples. Glob Planet Chang 32:33–47
Stanev EV, Staneva JV, Roussenov VM (1997) On the Black Sea water mass formation. Model sensitivity study to atmospheric forcing and parameterization of physical processes. J Mar Syst 13:245–272
Stanev E, Le Traon P, Peneva E (2000) Sea level variations and their dependency on meteorological and hydrological forcing: analysis of altimeter and surface data for the Black Sea. J Geophys Res 105(170):203–17, 216
Stanev EV, Simeonov JA, Peneva EL (2001) Ventilation of Black Sea pycnocline by the Mediterranean plume. J. Mar. Sys. 31:77–97
Stanev EV, Bowman MJ, Peneva EL, Staneva JV (2003) Control of Black Sea intermediate water mass formation by dynamics and topography: comparison of numerical simulations, surveys and satellite data. J Mar Res 61:59–99
Stanev EV, Staneva J, Bullister JL, Murray JW (2004) Ventilation of the Black Sea pycnocline. Parameterization of convection, numerical simulations and validations against observed chlorofluorocarbon data. Deep-Sea Res 51/12:2137–2169
Stanev EV, He Y, Staneva J, Yakushev E (2014) Mixing in the Black Sea detected from the temporal and spatial variability of oxygen and sulfide—Argo float observations and numerical modelling. Biogeosciences 11:5707–5732
Staneva JV, Dietrich D, Stanev E, Bowman M (2001) Rim current and coastal eddy mechanisms in an eddy-resolving Black Sea general circulation model. J Mar Sys 3:137–157
Stashchuk N, Hutter K (2001) Modelling of waters exchange through the Strait of the Dardanelles. Cont Shelf Res 21:1361–1382. doi:10.1016/S0278-4343(01)00017-6
Trukhchev D, Stanev EV, Balashov GD, Miloshev GD, Roussenov VM (1985) Some singularities of meso-scale structure of hydrological fields in the western part of the Black Sea. Oceanologiya 25(4):572–577 (in Russian)
Umlauf L, Burchard H (2003) A generic length-scale equation for geophysical turbulence models. J Mar Res 6:235–265
Ünlüata Ü, Oğuz T, Latif MA, E. E. (1990) On the physical oceanography of the Turkish straits. In: Pratt LJ (ed) The physical oceanography of sea straits. Kluwer Acad, Dordrecht, pp 25–60
Volkov DL, Johns WE, Belonenko TV (2016) Dynamic response of the Black Sea elevation to intraseasonal fluctuations of the Mediterranean sea level. Geophys Res Lett 43:283–290. doi:10.1002/2015GL066876
Yuksel Y, Ayat B, Ozturk MN, Aydogan B, Güler I, Cevik EO, Yalçıner AC (2008) Responses of the stratified flows to their driving conditions—a field study. Ocean Eng 35:1304–1321. doi:10.1016/j.oceaneng.2008.06.006
Zatsepin AG, Ginzburg AI, Kostianoy AG, Kremenetskiy VV, Krivosheya VG, Stanichny SV, Poulain P-M (2003) Observations of Black Sea mesoscale eddies and associated horizontal mixing. J Geophys Res 108(C8):3246. doi:10.1029/2002JC001390
Zhang Y, Baptista AM (2008) SELFE: a semi-implicit Eulerian-Lagrangian finite element model for cross-scale ocean circulation. Ocean Mod 21(3–4):71–96
Zhang Y, Ateljevich E, Yu H-C, Wu C-H, Yu JCS (2015) A new vertical coordinate system for a 3D unstructured-grid model. Ocean Model 85:16–31
Zhang YJ, Stanev EV, Grashorn S (2016a) Unstructured-grid model for the North Sea and Baltic Sea: validation against observations. Ocean Model 97:91–108
Zhang YJ, Fei Y, Stanev EV, Grashorn S (2016b) Seamless cross-scale modelling with SCHISM. Ocean Model 102:64–81
Zhou F, Shapiro G, Wobus F (2014) Cross-shelf exchange in the northwestern Black Sea. J Geophys Res Oceans 119:2143–2164. doi:10.1002/2013JC009484
Zhurbas VM, Zatsepin AG, Grigor’eva YV, Eremeev VN, Kremenetsky VV, Motyzhev SV, Poyarkov SG, Poulain P-M, Stanichny SV, Soloviev DM (2004) Water circulation and characteristics of currents of different scales in the upper layer of the Black Sea from drifter. Oceanology 44(1):30–43
Acknowledgements
We are grateful to the two anonymous reviewers for their constructive comments. One of their comments motivated us to add a supplementary material section where we summarize comparison with observations and previous studies. The hydrological for the Marmara Sea data was kindly provided by J. Chiggiato. Thanks are due to Ingeborg Noehren for the technical preparation of the figures. This study benefited from the support from the Black Sea Copernicus Marine Forecasting Centre and from the data collected in the frame of EU-funded EAIMS project. The authors gratefully acknowledge the computing time granted by the John von Neumann Institute for Computing (NIC) and provided on the supercomputers JUROPA and JURECA at Jülich Supercomputing Centre (JSC). Part of the information in Fig. 12 is reproduced from a publication in JGR.
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Stanev, E.V., Grashorn, S. & Zhang, Y.J. Cascading ocean basins: numerical simulations of the circulation and interbasin exchange in the Azov-Black-Marmara-Mediterranean Seas system. Ocean Dynamics 67, 1003–1025 (2017). https://doi.org/10.1007/s10236-017-1071-2
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DOI: https://doi.org/10.1007/s10236-017-1071-2