Editorial Type:
Article
Article Type:
Research Article

Influence of the Meridional Overturning Circulation on Tropical–Subtropical Pathways

Markus Jochum Massachusetts Institute of Technology, MIT–WHOI Joint Program in Physical Oceanography, Cambridge, Massachusetts

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Paola Malanotte-Rizzoli Massachusetts Institute of Technology, MIT–WHOI Joint Program in Physical Oceanography, Cambridge, Massachusetts

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Print Publication:
01 May 2001
DOI:
https://doi.org/10.1175/1520-0485(2001)031<1313:IOTMOC>2.0.CO;2
Page(s):
1313–1323
Restricted access

Abstract

An ocean GCM is used for idealized studies of the Atlantic circulation in a square basin. The subtropical, the tropical, and the equatorial gyres are produced by forcing the model with a wind stress profile having only latitudinal dependence. The goal is to understand the effect of the meridional overturning circulation (MOC) on the Atlantic intergyre exchanges. The MOC is imposed by prescribing an inflow all along the southern boundary and an outflow at the northern boundary. The results indicate that the northward flow of the MOC has a crucial effect on the subtropical–tropical pathways. In this idealized configuration the North Atlantic wind field creates a basinwide potential vorticity barrier. Therefore, the water subducted in the North Atlantic has to flow to the western boundary before turning equatorward. This is shown by the trajectories of floats injected in a band of northern latitudes. The warm water return flow of the MOC inhibits this pathway and reduces the inflow of North Atlantic waters into the equator from 10 Sv in the purely wind-driven case to 2 Sv (Sv ≡ 106 m3 s−1). Thus, the equatorial thermocline consists mainly of water from the South Atlantic. The analysis of synthetic float trajectories reveals two distinct routes for the return flow of the MOC, the first one occurring in the intermediate layers along the western boundary and the second all across the basin in the surface layer. The surface path starts with water subducting in the South Atlantic subtropical gyre, flowing within the North Brazil Current to the equator, entering the Equatorial Undercurrent (EUC), becoming entrained into the tropical mixed layer, and finally flowing northward in the Ekman layer. The contribution of thermocline water to the MOC return flow is negligible.

Corresponding author’s address: Markus Jochum, MIT, Room 54-1511, 77, Massachusetts Avenue, Cambridge, MA 02139.

Email: markus@ocean.mit.edu

Abstract

An ocean GCM is used for idealized studies of the Atlantic circulation in a square basin. The subtropical, the tropical, and the equatorial gyres are produced by forcing the model with a wind stress profile having only latitudinal dependence. The goal is to understand the effect of the meridional overturning circulation (MOC) on the Atlantic intergyre exchanges. The MOC is imposed by prescribing an inflow all along the southern boundary and an outflow at the northern boundary. The results indicate that the northward flow of the MOC has a crucial effect on the subtropical–tropical pathways. In this idealized configuration the North Atlantic wind field creates a basinwide potential vorticity barrier. Therefore, the water subducted in the North Atlantic has to flow to the western boundary before turning equatorward. This is shown by the trajectories of floats injected in a band of northern latitudes. The warm water return flow of the MOC inhibits this pathway and reduces the inflow of North Atlantic waters into the equator from 10 Sv in the purely wind-driven case to 2 Sv (Sv ≡ 106 m3 s−1). Thus, the equatorial thermocline consists mainly of water from the South Atlantic. The analysis of synthetic float trajectories reveals two distinct routes for the return flow of the MOC, the first one occurring in the intermediate layers along the western boundary and the second all across the basin in the surface layer. The surface path starts with water subducting in the South Atlantic subtropical gyre, flowing within the North Brazil Current to the equator, entering the Equatorial Undercurrent (EUC), becoming entrained into the tropical mixed layer, and finally flowing northward in the Ekman layer. The contribution of thermocline water to the MOC return flow is negligible.

Corresponding author’s address: Markus Jochum, MIT, Room 54-1511, 77, Massachusetts Avenue, Cambridge, MA 02139.

Email: markus@ocean.mit.edu

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  • Arhan, M., H. Mercier, B. Bourles, and Y. Gouriou, 1998: Two hydrographic sections across the Atlantic at 7°30′N and 4°30′S. Deep-Sea Res., in press.

  • Fratantoni, D., 1996: On the pathways and mechanisms of upper ocean mass transport across the Atlantic equator. Ph.D. thesis, University of Miami, 250 pp.

  • ——, W. Johns, and T. Townsend, 1995: Rings of the North Brazil Current. J. Geophys. Res.,100, 10 633–10 654.

  • Johns, W., T. Lee, R. Beardsley, J. Candela, R. Limeburner, and B. Castro, 1998: Annual cycle and variability of the North Brazil Current. J. Phys. Oceanogr.,28, 103–128.

  • Kawase, M., and J. Sarmiento, 1985: Nutrients in the Atlantic thermocline. J. Geophys. Res.,90, 8960–8979.

  • Liu, Z., 1994: A simple model of the mass exchange between the subtropical and tropical ocean. J. Phys. Oceanogr.,24, 1153–1165.

  • ——, and S. Philander, 1995: How different wind stress patterns affect the tropical–subtropical circulations of the upper ocean. J. Phys. Oceanogr.,25, 449–462.

  • ——, ——, and R. Pacanowski, 1994: A GCM study of tropical–subtropical upper-ocean exchange. J. Phys. Oceanogr.,24, 2606–2623.

  • McCreary, J., and P. Lu, 1994: Interaction between the subtropical and equatorial ocean circulations: The subtropical cell. J. Phys. Oceanogr.,24, 466–497.

  • Oliger, O., and A. Sundstrom, 1978: Theoretical and practical aspects of some initial boundary value problems in fluid dynamics. J. Appl. Math.,35, 419–446.

  • Pedlosky, J., 1987: An inertial theory for the equatorial undercurrent. J. Phys. Oceanogr.,17, 1978–1985.

  • ——, 1996: Ocean Circulation Theory. Springer, 454 pp.

  • Philander, S., 1990: El Niño, La Niña and the Southern Oscillation. Academic Press, 293 pp.

  • Schmitz, W., and M. McCartney, 1993: On the North Atlantic circulation. Rev. Geophys.,31, 29–49.

  • Schott, F., L. Stramma, and J. Fischer, 1995: The warm water regime into the western tropical Atlantic boundary regime, spring 1994. J. Geophys. Res.,100, 24 745–24 760.

  • Spall, M., and A. Robinson, 1989: A new open ocean, hybrid coordinate primitive equation model. Math. Comp. Simul.,31, 241–269.

  • Stevens, D., 1990: On open boundary conditions for three dimensional primitive equation ocean circulation models. Geophys. Astrophys. Fluid Dyn.,51, 103–133.

  • Tsuchiya, M., R. Lukas, R. Fine, E. Firing, and E. Lindstrom, 1989:Source waters of the Pacific Equatorial Undercurrent. Progress in Oceanography, Vol. 23, Pergamon, 101–147.

  • Warren, B., 1981: Deep circulation in the World Ocean. Evolution of Physical Oceanography, The MIT Press, 6–41.

  • Wilson, W., and W. Johns, 1997: Velocity structure and transport in the windward passage. Deep-Sea Res.,44, 487–520.

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