Mechanisms for Spreading of Mediterranean Water in Coarse-Resolution Numerical Models

R. Gerdes Alfred-Wegener-Institute for Polar and Marine Research, Bremerhaven, Germany

Search for other papers by R. Gerdes in
Current site
Google Scholar
PubMed
Close
,
C. Köberle Alfred-Wegener-Institute for Polar and Marine Research, Bremerhaven, Germany

Search for other papers by C. Köberle in
Current site
Google Scholar
PubMed
Close
,
A. Beckmann Alfred-Wegener-Institute for Polar and Marine Research, Bremerhaven, Germany

Search for other papers by A. Beckmann in
Current site
Google Scholar
PubMed
Close
,
P. Herrmann Institut für Meereskunde, Kiel, Germany

Search for other papers by P. Herrmann in
Current site
Google Scholar
PubMed
Close
, and
J. Willebrand Institut für Meereskunde, Kiel, Germany

Search for other papers by J. Willebrand in
Current site
Google Scholar
PubMed
Close
Restricted access

Abstract

Different processes have been proposed to explain the large-scale spreading of Mediterranean Water (MW) in the North Atlantic, however, no systematic study comparing the efficiency of different processes is yet available. Here, the authors present a series of experiments in a unified framework that is designed to quantify the effects of several physical processes on the spreading of MW in an idealized model of the North Atlantic. The common technique of restoring temperature and salinity to an observed distribution near the Mediterranean inflow fails to produce an adequate amount of MW because the eastern boundary region near the MW inflow is rather quiescent in models. Diapycnal processes like double diffusion and cabbeling turn out too inefficient to alone account for the large-scale MW anomaly. However, with a preexisting anomaly, double diffusion leads to a considerable northward and zonal redistribution of MW. The density anomaly induced by cabbeling curtails the zonal spreading of MW while it increases the northward spreading. With isopycnal mixing and the weak mean flow that prevails in the outflow region, a spatial distribution of the MW anomaly is obtained that is inconsistent with observations. Unrealistically high diffusion coefficients would be necessary to reproduce the observed salt flux into the Atlantic. The most effective process in the experiments is the volume flux associated with the Atlantic–Mediterranean exchange. The current system that is established in response to the inflow of MW into the Atlantic carries the anomaly almost 30° of longitude into the basin and along the eastern margin up to the northeastern corner of the domain and farther along the northern boundary.

Corresponding author address: Dr. Rüdiger Gerdes, Alfred-Wegener-Institute for Polar and Marine Research Am Handelshafen 12, D-27570 Bremerhaven, Germany.

Abstract

Different processes have been proposed to explain the large-scale spreading of Mediterranean Water (MW) in the North Atlantic, however, no systematic study comparing the efficiency of different processes is yet available. Here, the authors present a series of experiments in a unified framework that is designed to quantify the effects of several physical processes on the spreading of MW in an idealized model of the North Atlantic. The common technique of restoring temperature and salinity to an observed distribution near the Mediterranean inflow fails to produce an adequate amount of MW because the eastern boundary region near the MW inflow is rather quiescent in models. Diapycnal processes like double diffusion and cabbeling turn out too inefficient to alone account for the large-scale MW anomaly. However, with a preexisting anomaly, double diffusion leads to a considerable northward and zonal redistribution of MW. The density anomaly induced by cabbeling curtails the zonal spreading of MW while it increases the northward spreading. With isopycnal mixing and the weak mean flow that prevails in the outflow region, a spatial distribution of the MW anomaly is obtained that is inconsistent with observations. Unrealistically high diffusion coefficients would be necessary to reproduce the observed salt flux into the Atlantic. The most effective process in the experiments is the volume flux associated with the Atlantic–Mediterranean exchange. The current system that is established in response to the inflow of MW into the Atlantic carries the anomaly almost 30° of longitude into the basin and along the eastern margin up to the northeastern corner of the domain and farther along the northern boundary.

Corresponding author address: Dr. Rüdiger Gerdes, Alfred-Wegener-Institute for Polar and Marine Research Am Handelshafen 12, D-27570 Bremerhaven, Germany.

Save
  • Arhan, M., 1987: On the large scale dynamics of the Mediterranean outflow. Deep-Sea Res.,34, 1187–1208.

  • ——, A. Colin de Verdière, and L. Mémery, 1994: The eastern boundary of the subtropical North Atlantic. J. Phys. Oceanogr.,24, 1295–1316.

  • Armi, L., and D. B. Haidvogel, 1982: Effects of variable and anisotropic diffusivities in a steady-state diffusion model. J. Phys. Oceanogr.,12, 785–794.

  • Beckmann, A., C. W. Böning, C. Köberle, and J. Willebrand, 1994:Effects of increased horizontal resolution in a simulation of the North Atlantic Ocean. J. Phys. Oceanogr.,24, 326–344.

  • Bryan, F. O., and W. R. Holland, 1989: A high resolution simulation of the wind- and thermohaline-driven circulation of the North Atlantic Ocean. Proc. ’Aha Huliko’a Hawaiian Winter Workshop, Hawaii, University of Hawaii at Manoa, 99–115.

  • Bryden, H. L., and T. H. Kinder, 1991: Steady two-layer exchange through the Strait of Gibraltar. Deep-Sea Res.,38, S445–S463.

  • Cox, M. D., 1987: Isopycnal diffusion in a z-coordinate ocean model. Ocean Modelling, (unpublished manuscripts), 74, 1–5.

  • ——, 1989: An idealized model of the world ocean. Part I: The global scale water masses. J. Phys. Oceanogr.19, 1730–1752.

  • ——, and K. Bryan, 1984: Numerical model of the ventilated thermocline. J. Phys. Oceanogr.,14, 674–687.

  • Farrow, D. E., and D. P. Stevens, 1995: A new tracer advection scheme for Bryan and Cox type ocean general circulation models. J. Phys. Oceanogr.,25, 1731–1741.

  • Fukumori, I., 1991: Circulation about the Mediterranean tongue: An analysis of an EOF based model ocean. Progress in Oceanography, Vol. 27, Pergamon, 197–224.

  • Gargett, A. E., and G. Holloway, 1992: Sensitivity of the GFDL ocean model to different diffusivities for heat and salt. J. Phys. Oceanogr.,22, 1158–1177.

  • Gerdes, R., and C. Köberle, 1995: On the influence of DSOW in a numerical model of the North Atlantic general circulation. J. Phys. Oceanogr.,25, 2624–2642.

  • ——, ——, and J. Willebrand, 1991: The influence of numerical advection schemes on the results of ocean general circulation models. Climate Dyn.,5, 211–226.

  • Hecht, M. W., W. R. Holland, and P. I. Rasch, 1995: Upwind-weighted advection schemes for ocean tracer transport: An evaluation in a passive tracer context. J. Geophys. Res.,100 (C10), 20 763–20 778.

  • Hsieh, W. W., M. K. Davey, and R. Wajsowicz, 1983: Free Kelvin wave in finite-difference numerical model. J. Phys. Oceanogr.,13, 1383–1397.

  • Käse, R. H., and W. Zenk, 1987: Reconstructed Mediterranean salt lens trajectories. J. Phys. Oceanogr.,17, 158–163.

  • ——, and ——, 1996: Structure of the Mediterranean Water and meddy characteristics in the Northeastern Atlantic. The Warmwatersphere of the North Atlantic Ocean, W. Krauss, Ed., Borntraeger, 446 pp.

  • Klinck, J. M., 1995: Thermohaline structure of an eddy-resolving North Atlantic model: The influence of boundary conditions. J. Phys. Oceanogr.,25, 1174–1195.

  • Levitus, S., 1982: Climatological Atlas of the World Ocean. NOAA Prof. Paper No. 13, U.S. Govt. Printing Office, 173 pp.

  • McCartney, M. S., and L. D., Talley, 1982: The subpolar mode water of the North Atlantic Ocean. J. Phys. Oceanogr.,12, 1169–1188.

  • McDougall, T. J., 1987: Thermobaricity, cabbeling, and water-mass conversion. J. Geophys. Res.,92 (C5), 5448–5464.

  • Ochoa, J., and N. A. Bray, 1991: Water mass exchange in the Gulf of Cadiz. Deep-Sea Res.,38 (Suppl.), S465–S503.

  • Pacanowski, R., K. Dixon, and A. Rosati, 1991: The G.F.D.L. modular ocean model users guide. GFDL Ocean Group Tech. Rep. No. 2, Geophysical Fluid Dynamics Laboratory/Princeton University, Princeton, NJ. [Available from Geophysical Fluid Dynamics Laboratory, P.O. Box 308, Princeton, NJ 08542.].

  • Prince, J. F., and M. O’Neill Baringer, 1994: Outflow and deep water production by marginal seas. Progress in Oceanography, Vol. 33, Pergamon, 161–200.

  • ——, T. K. McKee, J. R. Valdes, P. L. Richardson, and L. Armi, 1986: SOFAR float Mediterranean outflow experiment, 1984–1985. Woods Hole Oceanographic Institution Tech. Rep. WHOI-86-31, 199 pp. [Available from Woods Hole Oceanographic Institution, Woods Hole, MA 02543.].

  • Redi, M. H., 1982: Oceanic isopycnal mixing by coordinate rotation. J. Phys. Oceanogr.,12, 1154–1158.

  • Reid, J. L., 1979: On the contribution of the Mediterranean Sea outflow to the Norwegian-Greenland Sea. Deep-Sea Res.,26A, 1199–1223.

  • ——, 1994: On the total geostrophic circulation of the North Atlantic Ocean: Flow patterns, tracers, and transports. Progress in Oceanography, Vol. 33, Pergamon, 33, 1–92.

  • Richardson, P. L., D. Walsh, L. Armi, M. Schröder, and J. F. Price, 1989: Tracking three meddies with SOFAR floats. J. Phys. Oceanogr.,19, 371–383.

  • Ruddick, B., 1983: A practical indicator of the stability of the water column to double-diffusive activity. Deep-Sea Res.,30, 1105–1107.

  • Sarmiento, J. L., and K. Bryan, 1982: An ocean transport model for the North Atlantic. J. Geophys. Res.,87, 8047–8056.

  • Schmitt, R. W., 1979: Flux measurements on salt fingers at an interface. J. Mar. Res.,37, 419–436.

  • Schopp, R., and M. Arhan, 1986: Ventilated middepth circulation model for the eastern North Atlantic. J. Phys. Oceanogr.,16, 344–357.

  • Spall, M. A., 1990: Circulation in the Canary Basin: A model/data analysis. J. Geophys. Res.,95 (C6), 9611–9628.

  • ——, 1994: Mechanism for low-frequency variability and salt flux in the Mediterranean salt tongue. J. Geophys. Res.,99 (C5), 10 121–10 129.

  • Stanev, E. V., 1992: Numerical experiments on the spreading of Mediterranean water in the North Atlantic. Deep-Sea Res.,39, 1747–1766.

  • Turner, J. S., 1973: Buoyancy Effects in Fluids. Cambridge University Press, 367 pp.

  • Tziperman, E., 1987: The Mediterranean outflow as an example of a deep buoyancy-driven flow. J. Geophys. Res.,92 (C13), 14 510–14 520.

  • Wijfels, S. E., R. W. Schmitt, H. L. Bryden, and A. Stigebrandt, 1992: On the transport of fresh water by the oceans. J. Phys. Oceanogr.,22, 155–162.

  • Zalesak, S. T., 1979: Fully multi-dimensional flux-corrected transport algorithms for fluids. J. Comput. Phys.,31, 335–362.

All Time Past Year Past 30 Days
Abstract Views 0 0 0
Full Text Views 256 96 47
PDF Downloads 75 38 5