Transition to Aperiodic Variability in a Wind-Driven Double-Gyre Circulation Model

Multiple equilibria as well as periodic and aperiodic solution regimes are obtained in a barotropic model of the midlatitude ocean’s double-gyre circulation. The model circulation is driven by a steady zonal wind profile that is symmetric with respect to the square basin’s zonal axis of north‐south symmetry, and dissipated by lateral friction. As the intensity of the wind forcing increases, an antisymmetric double-gyre flow evolves through a pitchfork bifurcation into a pair of steady mirror-symmetric solutions in which either the subtropical or the subpolar gyre dominates. In either one of the two asymmetric solutions, a pair of intense recirculation vortices forms close to and on either side of the point where the two western boundary currents merge to form the eastward jet. To the east of this dipole, a spatially damped stationary wave arises, and an increase in the steady forcing amplifies the meander immediately to the east of the recirculating vortices. During this process, the transport of the weaker gyre remains nearly constant while the transport of the stronger gyre increases. For even stronger forcing, the two steady solution branches undergo Hopf bifurcation, and each asymmetric solution gives rise to an oscillatory mode, whose subannual period is of 3.5‐6 months. These two modes are also mirror-symmetric in space. The time-average difference in transport between the stronger and the weaker gyre is reduced as the forcing increases further, while the weaker gyre tends to oscillate with larger amplitude than the stronger gyre. Once the average strength of the weaker gyre on each branch equals the stronger gyre’s, the solution becomes aperiodic. The transition of aperiodic flow occurs through a global bifurcation that involves a homoclinic orbit. The subannual oscillations persist and stay fairly regular in the aperiodic solution regime, but they alternate now with a new and highly energetic, interannual oscillation. The physical causes of these two oscillations—as well as of a third, 19-day oscillation—are discussed. During episodes of the high-amplitude, interannual oscillation, the solution exhibits phases of either the subtropical or subpolar gyre being dominant. Even lower-frequency, interdecadal variability arises due to an irregular alternation between subannual and interannual modes of oscillation.

[1]  M. Ghil,et al.  Baroclinic and barotropic aspects of the wind-driven ocean circulation☆ , 2002 .

[2]  Michael Ghil,et al.  Solving problems with GCMs: General circulation models and their role in the climate modeling hierarchy , 2000 .

[3]  Michael Ghil,et al.  DAMÉE-NAB: the base experiments , 2000 .

[4]  J. McWilliams,et al.  Quasigeostrophic Dynamics of the Western Boundary Current , 1999 .

[5]  James C. McWilliams,et al.  Large-Scale, Low-Frequency Variability in Wind-Driven Ocean Gyres , 1999 .

[6]  Henk A. Dijkstra,et al.  Imperfections of the North-Atlantic wind-driven ocean circulation: continental geometry and windstress shape , 1999 .

[7]  François W. Primeau,et al.  Multiple Equilibria of a Double-Gyre Ocean Model with Super-Slip Boundary Conditions , 1998 .

[8]  M. Ghil,et al.  Trends, interdecadal and interannual oscillations in global sea-surface temperatures , 1998 .

[9]  S. Meacham,et al.  The Dynamics of a Simple Baroclinic Model of the Wind-Driven Circulation , 1998 .

[10]  Éric Simonnet Quelques problèmes numériques associés aux écoulements géophysiques , 1998 .

[11]  S. Meacham,et al.  Instabilities of a steady, barotropic, wind-driven circulation , 1997 .

[12]  Henk A. Dijkstra,et al.  Temporal variability of the wind-driven quasi-geostrophic double gyre ocean circulation: Basic bifurcation diagrams , 1997 .

[13]  S. Meacham,et al.  Barotropic, wind-driven circulation in a small basin , 1997 .

[14]  S. Meacham,et al.  The dynamics of an equivalent-barotropic model of the wind-driven circulation , 1997 .

[15]  V. A. Sheremet,et al.  Eigenanalysis of the two-dimensional wind-driven ocean circulation problem , 1997 .

[16]  Michael Ghil,et al.  Tracking Nonlinear Solutions with Simulated Altimetric Data in a Shallow-Water Model* , 1997 .

[17]  Frank O. Bryan,et al.  Modeling the Gulf Stream System: How far from reality? , 1996 .

[18]  Richard Smith,et al.  Global Ocean Circulation from Satellite Altimetry and High-Resolution Computer Simulation , 1996 .

[19]  Q. Zheng,et al.  A Numerical Simulation of Wind Stress and Topographic Effects on the Kuroshio Current Path near Taiwan , 1996 .

[20]  C. Deser,et al.  Upper-Ocean Thermal Variations in the North Pacific during 1970–1991 , 1996 .

[21]  Michael Ghil,et al.  Interdecadal Variability in a Hybrid Coupled Ocean-Atmosphere Model , 1996 .

[22]  John D. McCalpin,et al.  Phenomenology of the low-frequency variability in a reduced-gravity, quasigeostrophic double-gyre model , 1996 .

[23]  Andrew W. Robertson,et al.  Interdecadal variability over the North Pacific in a multi-century climate simulation , 1996 .

[24]  Tong Lee,et al.  Propagation and Growth of Gulf Stream Meanders between 75° and 45°W , 1996 .

[25]  F. Schott,et al.  The Western Boundary Circulation of the Subtropical Warmwatersphere , 1996 .

[26]  Joseph Pedlosky,et al.  Ocean Circulation Theory , 1996 .

[27]  Michael Ghil,et al.  Successive bifurcations in a shallow-water model applied to the wind-driven ocean circulation , 1995 .

[28]  V. Sheremet,et al.  Analysis of the barotropic model of the subtropical gyre in the ocean for finite Reynolds numbers. Part II. , 1995 .

[29]  B. Brügge Near‐surface mean circulation and kinetic energy in the central North Atlantic from drifter data , 1995 .

[30]  Glenn R. Ierley,et al.  Multiple solutions and advection-dominated flows in the wind-driven circulation. Part I: Slip , 1995 .

[31]  Glenn R. Ierley,et al.  Symmetry-Breaking Multiple Equilibria in Quasigeostrophic, Wind-Driven Flows , 1995 .

[32]  Michael Ghil,et al.  Multiple equilibria and stable oscillations in thermosolutal convection at small aspect ratio , 1995, Journal of Fluid Mechanics.

[33]  Michael Ghil,et al.  Multiple Equilibria, Periodic, and Aperiodic Solutions in a Wind-Driven, Double-Gyre, Shallow-Water Model , 1995 .

[34]  Michael Ghil,et al.  Software expedites singular‐spectrum analysis of noisy time series , 1995, Eos, Transactions American Geophysical Union.

[35]  T. P. Barnett,et al.  Causes of Decadal Climate Variability over the North Pacific and North America , 1994, Science.

[36]  Syukuro Manabe,et al.  Interdecadal Variations of the Thermohaline Circulation in a Coupled Ocean-Atmosphere Model , 1993 .

[37]  Hiroshi Ichikawa,et al.  Temporal and spatial variability of volume transport of the Kuroshio in the East China Sea , 1993 .

[38]  Michael Ghil,et al.  Multiple equilibria in thermosolutal convection due to salt-flux boundary conditions , 1992, Journal of Fluid Mechanics.

[39]  P. Gent,et al.  Boundary Current Separation in a Quasigeostrophic, Eddy-resolving Ocean Circulation Model , 1992 .

[40]  G. Ierley,et al.  Viscous Instabilities in the Western Boundary Layer , 1991 .

[41]  Dale B. Haidvogel,et al.  Dynamical simulations of filament formation and evolution in the Coastal Transition Zone , 1991 .

[42]  Glen Gawarkiewicz,et al.  Formation and Maintenance of Shelfbreak Fronts in an Unstratified Flow , 1991 .

[43]  Dale B. Haidvogel,et al.  A semi-spectral primitive equation ocean circulation model using vertical sigma and orthogonal curvilinear horizontal coordinates , 1991 .

[44]  B. Moro On the non-linear Munk model. II, Stability , 1989 .

[45]  R. Temam Infinite Dimensional Dynamical Systems in Mechanics and Physics Springer Verlag , 1993 .

[46]  R. Evans,et al.  Temporal variations in the separation of Brazil and Malvinas Currents , 1988 .

[47]  B. Moro On the nonlinear munk model. I. Steady flows , 1988 .

[48]  Stephen J. Auer Five‐year climatological survey of the Gulf Stream system and its associated rings , 1987 .

[49]  S. Childress,et al.  Topics in geophysical fluid dynamics. Atmospheric dynamics, dynamo theory, and climate dynamics. , 1987 .

[50]  C. Böning On the influence of frictional parameterization in wind-driven ocean circulation models , 1986 .

[51]  T. Rossby,et al.  The Structure and Transport of the Gulf Stream at 73°W , 1985 .

[52]  S. A. Robertson,et al.  NONLINEAR OSCILLATIONS, DYNAMICAL SYSTEMS, AND BIFURCATIONS OF VECTOR FIELDS (Applied Mathematical Sciences, 42) , 1984 .

[53]  Keisuke Mizuno,et al.  Annual and Interannual Variability in the Kuroshio Current System , 1983 .

[54]  P. Holmes,et al.  Nonlinear Oscillations, Dynamical Systems, and Bifurcations of Vector Fields , 1983, Applied Mathematical Sciences.

[55]  W. Briggs A new class of steady solutions of the barotropic vorticity equation , 1980 .

[56]  K. Wyrtki,et al.  Eddy energy in the oceans , 1976 .

[57]  George Veronis,et al.  Wind-driven ocean circulation--Part II: Numerical solution of the nonlinear problem , 1966 .

[58]  George Veronis,et al.  An Analysis of Wind-Driven Ocean Circulation with a Limited Number of Fourier Components , 1963 .

[59]  K. Bryan,et al.  A Numerical Investigation of a Nonlinear Model of a Wind-Driven Ocean , 1963 .

[60]  Walter Munk,et al.  ON THE WIND-DRIVEN OCEAN CIRCULATION , 1950 .

[61]  H. Stommel,et al.  The westward intensification of wind‐driven ocean currents , 1948 .