1. Introduction
Midlatitude gyre flows, confined within closed basins, produce a relatively shallow thermocline. In contrast, the Southern Ocean’s unique geometry permits the Antarctic Circumpolar Current (ACC) to circumnavigate the globe, accompanied by much deeper stratification. Many studies have shown that the stratification generated in the ACC pervades the global ocean below roughly 500-m depth (Toggweiler and Samuels 1995; Gnanadesikan 1999; Wolfe and Cessi 2010; Kamenkovich and Radko 2011; Nikurashin and Vallis 2012; Munday et al. 2013). Therefore, to understand the global deep stratification, it is necessary to understand the dynamics of the ACC and how its equilibrium responds to changes in forcing. There is ample evidence that the wind stress forcing in the Southern Ocean has increased over decadal time scales (Marshall 2003; Toggweiler 2009) and may have been drastically reduced during the Last Glacial Maximum (Toggweiler and Russell 2008), suggesting that the equilibration of the Southern Ocean is of relevance for a wide range of climate problems.
The dominant paradigm for understanding the ACC stratification involves a balance between buoyancy transport by wind-driven upwelling, which tends to steepen the isopycnal slope and deepen the stratification, and baroclinic eddy transport, which reduces the isopycnal slope (Karsten et al. 2002). Thus, the stratification of the ACC is part of the broad fundamental problem in geophysical fluid dynamics and planetary atmospheres, sometimes referred to as “baroclinic equilibration,” of determining the statistical properties of eddy heat transport as a function of large-scale parameters (Green 1970; Stone 1972; Held 1999; Schneider 2006; Jansen and Ferrari 2012). The classical approach of assuming adjustment to a marginally baroclinically unstable state (Stone 1972; Straub 1993) is inappropriate for the ACC, not only because unstable modes always exist in the continuously stratified case, but also because oceanic eddies are generally too small to bring the classical criticality parameter to unity (Jansen and Ferrari 2012): the zonally and time-averaged baroclinic velocity is of the order of 0.2 m s−1, much larger than the phase speed of long baroclinic Rossby waves, which, with a deformation radius of about 15 km, is about 100 times smaller than the observed zonal-mean velocities.
Many eddy-permitting and eddy-resolving ACC modeling studies have examined the sensitivity of the isopycnal slope and associated thermal wind zonal transport on the wind stress forcing (Hallberg and Gnanadesikan 2001; Henning and Vallis 2005; Hallberg and Gnanadesikan 2006; Meredith and Hogg 2006; Hogg et al. 2008; Viebahn and Eden 2010; Farneti et al. 2010; Treguier et al. 2010; Abernathey et al. 2011; Meredith et al. 2012; Morrison and Hogg 2013; Munday et al. 2013). The sensitivity varies somewhat across models, and in all these studies, the eddy efficiency is a key parameter in determining the isopycnal slopes and resulting stratification depth.
Much of what is known about eddy equilibration comes from studies of baroclinic turbulence on a zonally symmetric beta plane (Held and Larichev 1996; Visbeck et al. 1997; Karsten et al. 2002; Thompson and Young 2006; Cessi 2008; Jansen and Ferrari 2012). In contrast, the ACC mesoscale turbulence is highly inhomogeneous in longitude, with pronounced “storm tracks” downstream of major topographic features such as the Kerguelen Plateau or Drake Passage. Most of the cross-frontal eddy exchange of mass and tracers occurs in such storm tracks (Treguier and McWilliams 1990; MacCready and Rhines 2001; Naveira-Garabato et al. 2011; Thompson and Sallée 2012). Accompanying these major topographic features are “stationary waves,” that is, meanders in the time-mean current with some characteristics of standing Rossby waves.1 To motivate our study, which is framed in terms of heat transport, in Fig. 1 we plot the vertically integrated divergence of the transient eddy heat flux in the ACC region, as calculated from the eddy-permitting Southern Ocean State Estimate (SOSE; Mazloff et al. 2010). We also plot the net mean (i.e., time averaged) and eddy (i.e., the departure from time average) heat transports across the ACC streamlines. (See section 2 for further details of the calculation.) The figure clearly illustrates that the eddy fluxes are an order of magnitude larger in the vicinity of the Kerguelen Plateau, Macquarie Ridge, East Pacific Rise, and Drake Passage, implying that these few regions make the dominant contribution to the net eddy heat transport across streamlines.
(left) The vertically integrated divergence of the transient eddy heat flux in the ACC region, calculated from SOSE. The black contours are contours of the barotropic transport streamfunction Ψ, defining streamlines of the ACC. (right) The integrated heat transport across streamlines. The total (
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(left) The vertically integrated divergence of the transient eddy heat flux in the ACC region, calculated from SOSE. The black contours are contours of the barotropic transport streamfunction Ψ, defining streamlines of the ACC. (right) The integrated heat transport across streamlines. The total (
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(left) The vertically integrated divergence of the transient eddy heat flux in the ACC region, calculated from SOSE. The black contours are contours of the barotropic transport streamfunction Ψ, defining streamlines of the ACC. (right) The integrated heat transport across streamlines. The total (
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The main goal of this study is to better understand how such localized orography affects the efficiency of eddies in the baroclinic equilibration process. We approach this problem by comparing the equilibration of idealized channel models with a topographic ridge to those with a flat bottom. Although the flat-bottomed case is not a realistic ACC model in itself, the comparison highlights the important role of topography in modifying eddy efficiency. Our paper is organized as follows: In section 2, we introduce an idealized ACC-like problem and describe how the stratification depth depends on the winds and the eddy heat flux across circumpolar contours. In section 3, we present solutions to this problem obtained from a primitive equation, eddy-resolving numerical simulation over a wide range of wind stress magnitudes. To aid in the interpretation of the results, section 4 develops analytical solutions for a two-layer, quasigeostrophic model that demonstrates the mechanism by which standing waves enhance the efficiency of baroclinic equilibration. In section 5, we examine the detailed structure of the cross-stream heat flux in the simulation, revealing the intense localization downstream of topography and the suppression of mixing away from the storm track. In section 6, we discuss the nature of baroclinic instability and wave propagation when topography is present and suggest the importance of locally unstable modes. Conclusions are summarized in section 7.
2. Eddy heat transport and thermocline depth
a. Description of an idealized problem
The goal of our study is to investigate how transient eddies determine the mean stratification in the presence of isolated topography in a simple context amenable to revealing the underlying physics. To this end, we study a highly idealized problem in which competition between wind and eddies completely determines the stratification. The key ingredients of this problem are as follows:
A zonally reentrant beta-plane channel domain, which permits a zonal current to develop. Using Cartesian coordinates (x, y, z), the channel dimensions are (Lx, Ly, H).
Westerly wind stress forcing, which drives an Eulerian-mean overturning. The form of the wind stress is τ = τ0 sin(πy/Ly), vanishing at the northern and southern boundaries.
Surface buoyancy restoring, which maintains a meridional sea surface temperature gradient. For simplicity, we make the gradient linear, with magnitude Δθ/Ly.
A quasi-adiabatic interior, with negligibly weak diapycnal mixing.
For the case with topography, a large topographic obstruction in the abyss.
Schematic depicting the idealized ACC-like problem in question. The black arrows indicate the westerly surface wind stress. The colored surfaces are isotherms, whose position at the surface is fixed by the surface thermal boundary condition.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Schematic depicting the idealized ACC-like problem in question. The black arrows indicate the westerly surface wind stress. The colored surfaces are isotherms, whose position at the surface is fixed by the surface thermal boundary condition.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Schematic depicting the idealized ACC-like problem in question. The black arrows indicate the westerly surface wind stress. The colored surfaces are isotherms, whose position at the surface is fixed by the surface thermal boundary condition.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Our choice of confining the flow in a channel with solid walls, where no flux of heat and no normal flow and no-slip boundary conditions are applied, removes the possibility of having a residual overturning circulation, at least in the low diffusivity limit considered here. Thus, our model ACC approaches the limit of zero residual circulation described by Johnson and Bryden (1989) or Kuo et al. (2005), in which mean and eddy-induced advection cancel completely. The vanishing residual circulation limit is a useful idealization of the complete ACC, in which there is a nonzero residual flow, but where large cancellations between the mean and eddies nevertheless occur (Speer et al. 2000; Hallberg and Gnanadesikan 2006; Volkov et al. 2010). In this way, the stratification in the channel is simply determined by a balance between wind-driven advection of buoyancy by the Ekman circulation, which steepens isopycnals and creates APE, and eddy buoyancy advection, which removes APE (Karsten et al. 2002). More generally, the Southern Ocean stratification is determined by a three-term heat balance involving Ekman and eddy heat transport and the residual circulation, which in turn depends on remote processes outside the channel. Gnanadesikan (1999) put forth a model of the global ocean pycnocline with three interacting components: North Atlantic sinking, low-latitude diffusive upwelling, and a Southern Ocean component that involves both Ekman and eddy transport (see also Wolfe and Cessi 2010; Nikurashin and Vallis 2012; Shakespeare and Hogg 2012). Our simplified geometry avoids introducing the additional unknown residual overturning, allowing us to focus purely on the eddy behavior. Our study should be interpreted not as a complete model of the global deep stratification but as a refinement of the Southern Ocean component of Gnanadesikan (1999), which must be coupled with other components to understand the global problem.
b. Scaling of the thermocline depth
A complementary approach, as first demonstrated by de Szoeke and Levine (1981), is to average along a meridional coordinate that follows the time-mean meanders of the ACC, so as to remove the standing eddy contribution, leaving a two-term balance between ageostrophic (i.e., Ekman driven) and transient eddy heat fluxes (Marshall et al. 1993; Hallberg and Gnanadesikan 2001; MacCready and Rhines 2001; Viebahn and Eden 2012).
In contrast to the zonal average, the streamwise average shows that the flat-bottomed and zonally asymmetric problems are both governed by the same fundamental balance of eddy and Ekman heat transport. The two perspectives are complementary, as demonstrated by Marshall et al. (1993), who show that the transient eddy flux across a streamline must approximately equal the sum of standing and transient eddy fluxes across an equivalent latitude circle. For heat fluxes, this means that 
Cartoon illustrating the interaction between standing and transient eddies. The black curve represents a time-mean streamline, and the arrows along this curve represent the cross-stream transient eddy flux.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Cartoon illustrating the interaction between standing and transient eddies. The black curve represents a time-mean streamline, and the arrows along this curve represent the cross-stream transient eddy flux.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Cartoon illustrating the interaction between standing and transient eddies. The black curve represents a time-mean streamline, and the arrows along this curve represent the cross-stream transient eddy flux.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
3. Numerical model results
a. Model configuration
The goal of the model is to realize the system described above (and illustrated in Fig. 2) as simply as possible, while resolving the eddy heat flux. The code solves the hydrostatic Boussinesq equations in Cartesian coordinates on the β plane using the Massachusetts Institute of Technology general circulation model (MITgcm; Marshall et al. 1997a,b). The model grid and numerical parameters are nearly identical to those described in Abernathey et al. (2011), to which the reader is referred for further details. The domain is a box Lx = 2000 km × Ly = 2000 km × H = 2985 m. The grid spacing is 5 km in the horizontal. There are 40 levels in the vertical, spaced 10 m apart at the surface and increasing to 200 m at depth. Linear bottom drag is applied in the bottom level of the model with a coefficient r = 1.1 × 10−3 m s−1. With a deformation radius of approximately 15 km, this model adequately resolves the mesoscale dynamics.
The model equilibrates after about 100 yr of spinup. Snapshots of the temperature field from the equilibrated state are shown in Fig. 4. The time-mean isotherms are also superimposed. While both simulations contain mesoscale eddies, the figure illustrates how the flat-bottomed case is statistically symmetric in x, while the ridge case contains a standing wave in the time-mean temperature field.
Colors show an instantaneous snapshot of the θ field from each reference experiment [(left) flat and (right) ridge]. The color scale ranges from 0° to 8°C. The field has been clipped at y = 1000 km, the meridional midpoint, to reveal a zonal cross section. The white contours are the time-mean isotherms 
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Colors show an instantaneous snapshot of the θ field from each reference experiment [(left) flat and (right) ridge]. The color scale ranges from 0° to 8°C. The field has been clipped at y = 1000 km, the meridional midpoint, to reveal a zonal cross section. The white contours are the time-mean isotherms
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Colors show an instantaneous snapshot of the θ field from each reference experiment [(left) flat and (right) ridge]. The color scale ranges from 0° to 8°C. The field has been clipped at y = 1000 km, the meridional midpoint, to reveal a zonal cross section. The white contours are the time-mean isotherms
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
b. Meridional heat transport and thermocline depth
The heat balance is illustrated in Fig. 5 for both the flat-bottomed and ridge reference experiments (τ0 = 0.2 N m−2). (Both can be considered streamwise-averaged views, since the Θ contours in the flat-bottomed case are zonally symmetric.) The upper panel demonstrates that 
(top) The heat transport components, 
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(top) The heat transport components,
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(top) The heat transport components,
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The difference in efficiency increases as the wind stress increases. Figure 6 (top-left panel) shows the thermocline depth as a function of wind stress, for both the flat and ridge experiments, for the following values of τ0: 0.0125, 0.025, 0.05, 0.1, 0.2, 0.4, and 0.8 N m−2. This range constitutes six successive doublings of the wind stress. It is clear that the dependence of h on τ0 is significantly weaker in the ridge case. The difference is even more pronounced when comparing the APE (bottom-left panel); for the strongest winds, the APE is over 4 times greater without topography. This is because as the winds increase, the geostrophic flow, and the associated temperature transport 
Comparison of global variables in flat-bottom (circles, solid lines) and ridge (triangles, stars, and dashed lines) experiments. (top left) The stratification depth h at the northern boundary, evaluated from (16). (top right) The magnitude of the meridional heat transport within the thermocline by the geostrophic flow 
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Comparison of global variables in flat-bottom (circles, solid lines) and ridge (triangles, stars, and dashed lines) experiments. (top left) The stratification depth h at the northern boundary, evaluated from (16). (top right) The magnitude of the meridional heat transport within the thermocline by the geostrophic flow
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Comparison of global variables in flat-bottom (circles, solid lines) and ridge (triangles, stars, and dashed lines) experiments. (top left) The stratification depth h at the northern boundary, evaluated from (16). (top right) The magnitude of the meridional heat transport within the thermocline by the geostrophic flow
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
We also ran the ridge experiment with a domain of increased zonal extent (4000 km rather than 2000 km) for the reference value of τ0 = 0.2 N m−2. One motivation for this experiment was to evaluate whether the relatively short domain was truncating the storm-track region and influencing the equilibration. The results are shown with the star symbol in Fig. 6; h, 
It is informative to also consider the heat transport decomposition in terms of zonal averages, which distinguishes between the standing and transient eddy components, defined in (10). Figure 7 shows that, with topography, as the wind forcing increases, it is primarily 
The different components of the meridional heat transport averaged over the middle of the domain from y = 800 km to y = 1600 km, plotted on a log–log scale, as a function of the wind stress amplitude τ0. The components are 
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The different components of the meridional heat transport averaged over the middle of the domain from y = 800 km to y = 1600 km, plotted on a log–log scale, as a function of the wind stress amplitude τ0. The components are
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The different components of the meridional heat transport averaged over the middle of the domain from y = 800 km to y = 1600 km, plotted on a log–log scale, as a function of the wind stress amplitude τ0. The components are
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
c. Zonal volume transport
Total (black) and thermal wind (red) zonal transports as a function of τ0 for the flat and ridge experiments.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Total (black) and thermal wind (red) zonal transports as a function of τ0 for the flat and ridge experiments.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Total (black) and thermal wind (red) zonal transports as a function of τ0 for the flat and ridge experiments.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
4. Eddy heat flux enhancement by standing waves
To understand the enhancement of eddy heat transport in the presence of topography, the resulting decrease of thermocline depth h, and the reduction of bottom flow, it is useful to examine a quasigeostrophic (QG) two-layer model, forced by wind stress τ and dissipated by bottom drag. This model, in which eddy effects are parameterized by downgradient diffusion of potential vorticity, quantifies and explains how the standing wave contributes to enhancing the efficiency of the eddy equilibration.
a. The standing wave response
b. The zonally averaged momentum and heat balances
c. Solution of the two-layer model
The solutions of the coupled system (33), (36), and (42) are easily obtained numerically. We illustrate the solutions by showing the maximum of U2 in the domain as a function of the wind stress amplitude as a solid line on the bottom-right panel of Fig. 6. The lines in Fig. 9 show the solutions for H1(y = L) with (dashed) and without (solid) the ridge as a function of τ0, assuming τ = τ0 sin(πy/Ly) and H1(y = 0) = 0, a choice well beyond the range of validity of the QG approximation. In this calculation, we assume the form K = Kref(τ0/τref)a, where α, Kref, and τref are constants. The values of the constants are chosen to best fit the primitive equation results of h as a function of τ0 for the flat-bottom case, with α ≃ 
The depth of the interface H1 at y = L, solution of (33), (36), and (42), as a function of the wind stress amplitude τ0, with (dashed line) and without (solid line) the ridge. The parameter values are the same as the primitive equation computations, except that the bottom drag is 20 times larger.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The depth of the interface H1 at y = L, solution of (33), (36), and (42), as a function of the wind stress amplitude τ0, with (dashed line) and without (solid line) the ridge. The parameter values are the same as the primitive equation computations, except that the bottom drag is 20 times larger.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The depth of the interface H1 at y = L, solution of (33), (36), and (42), as a function of the wind stress amplitude τ0, with (dashed line) and without (solid line) the ridge. The parameter values are the same as the primitive equation computations, except that the bottom drag is 20 times larger.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The total time-averaged interface height 
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The total time-averaged interface height
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The total time-averaged interface height
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(left) The local eddy heat transport 
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(left) The local eddy heat transport
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(left) The local eddy heat transport
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The QG model also correctly predicts the small amplitude of the bottom flow, so that the bottom drag term gives a small contribution to the momentum budget relative to the form drag and its dependence on the wind (solid line in Fig. 6, lower-right panel). For small bottom drag, U2 is insensitive to the value of r, and thus the slope varies almost linearly with r. The strong dependence of some aspects of the solution on r is a problematic aspect of the two-layer model.4
Notice that assuming the same value of K with or without topography leads to values of h that are comparatively smaller than those obtained in the eddy-resolving computations in the ridge case. The next section shows that the isolated ridge, while enhancing the eddy diffusivity near the ridge, suppresses it in the rest of domain, leading to an average diffusivity that is smaller than in the flat case. This additional response complicates the equilibration process.
5. Local cross-stream heat flux
In the flat-bottom case, the eddy statistics are homogeneous in the x direction, and the cross-stream heat fluxes (Ekman and transient eddy) are distributed evenly along the front. Prior studies of idealized circumpolar currents with topographic ridges (MacCready and Rhines 2001; Hallberg and Gnanadesikan 2001; Thompson 2010) have shown that eddy thickness fluxes (related to the eddy buoyancy flux) are concentrated in regions near and downstream of topographic ridges. A similar conclusion was reached by Thompson and Sallée (2012) in an analysis of altimetric data; they found that Lagrangian trajectories cross the ACC fronts preferentially in a few locations downstream of major topographic features such as the Drake Passage or Kerguelen Plateau. We find the same result in our simplified eddy-resolving computations: eddy heat fluxes are concentrated near and downstream of the ridge, unlike the QG prediction where the eddy fluxes are enhanced directly over the ridge, in direct proportion to the local gradient.
We plot 
Dependence of localization on winds
To illustrate the localization of the eddy fluxes as a function of the wind, we show in Fig. 12 (right panel) the cross-stream divergent flux, 
(left) The quantity |∇Θ| on the curve Θ = 0.96°C is contoured as a function of the arclength S and the wind strength τ0. (right) The cross-stream heat flux 
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(left) The quantity |∇Θ| on the curve Θ = 0.96°C is contoured as a function of the arclength S and the wind strength τ0. (right) The cross-stream heat flux
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(left) The quantity |∇Θ| on the curve Θ = 0.96°C is contoured as a function of the arclength S and the wind strength τ0. (right) The cross-stream heat flux
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
The maximum cross-stream heat flux is always downstream of the maximum of |∇Θ|, whose value along the same contour (also normalized by its maximum along the contour) is shown on the left panel of Fig. 12. It is clear that as the wind and amplitude of the stationary wave increase, the cross-stream heat flux becomes more localized downstream of the ridge, especially in the double-length computation. Moreover, the distributed portion of the cross-stream heat flux away from the ridge, characteristic of the flat-bottom case (cf. Fig. 11), which persists in the low wind regime, essentially vanishes for τ0 ≥ 0.05, leaving only the localized signal downstream of the ridge (and of |∇Θ|).
6. Local versus global eddy growth
The localization of the eddy fluxes just downstream of the ridge should be contrasted with their homogeneous nature in the flat-bottom case (cf. Fig. 11). This qualitative difference is associated with fundamentally different propagating properties of the eddies. We illustrate the eddy propagation in Fig. 13, a Hovmoeller diagram that shows the surface temperature anomalies (relative to the time mean) at y = 1000 km as a function of x and t: with the flat bottom (top panel), eddies propagate at a speed that is intermediate between the surface zonally averaged velocity (dashed black line) and the vertically and zonally averaged velocity (black solid line); with the ridge (lower panel), the transient eddies are almost stationary, moving eastward at a speed no larger than the vertically and zonally averaged velocity (black solid line) and much smaller than the surface velocity (dashed black line).
Hovmoeller diagram of surface temperature anomalies θ′ at y = 1000 km as a function of x and t (top) with and (bottom) without the ridge. The dashed line indicates the surface zonal velocity and the solid line indicates the barotropic zonal velocity.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Hovmoeller diagram of surface temperature anomalies θ′ at y = 1000 km as a function of x and t (top) with and (bottom) without the ridge. The dashed line indicates the surface zonal velocity and the solid line indicates the barotropic zonal velocity.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
Hovmoeller diagram of surface temperature anomalies θ′ at y = 1000 km as a function of x and t (top) with and (bottom) without the ridge. The dashed line indicates the surface zonal velocity and the solid line indicates the barotropic zonal velocity.
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
This difference in propagation indicates that in the flat case the eddies are generated and maintained through convective (global) instability, while with the ridge eddies are generated and maintained through absolute (local) instability (Merkine 1977; Pierrehumbert 1984). With topography, the generation of a standing meander locally increases the horizontal buoyancy gradients in the vicinity of the ridge (cf. the gray isotherms in Fig. 11), providing a local source of available potential energy that eddies can release. Furthermore, topography with a zonal slope reduces the stabilizing effect of β by orienting the wavenumber of the most unstable mode in a direction with a meridional, as well as a zonal, component (Chen and Kamenkovich 2013). The net result is a localized instability with larger growth rates than in the flat case and suppression of eddy growth away from the ridge.
An additional requirement for local growth is that the mean flow is slow enough to keep the eddies in place as they grow. The ridge reduces the speed of the mean zonal flow by reducing the bottom component relative to the flat case (cf. the bottom-right panel of Fig. 6). The dependence of local instability on the translational properties of the mean flow, as well as on its baroclinicity, is in sharp contrast with the global instability, where the growth rate depends on the shear, the stratification, and β, but not on the depth-averaged flow.
In summary, with the ridge, mean buoyancy gradients are locally enhanced and eddies propagate more slowly than in the flat case. Because there is a weak eastward propagation, the maximum in eddy activity is found downstream of the ridge. The difference in absolute versus convective instability is especially apparent in the initial transient development (Fig. 14, upper panel): in the flat case (upper-left panel of Fig. 14), there is a slow development of classical baroclinic instability beginning with “elevator” modes with purely meridional motion and eventually the development of a slow secondary instability in the orthogonal direction (Berloff et al. 2009) leading to finite-amplitude eddies. With the ridge (upper-right panel of Fig. 14), a stationary wave is immediately formed, with eddies quickly reaching finite amplitude in the lee of the ridge.
(top) Initial instability growth phase in each reference experiment, as reflected in the surface θ field. Note the two figures are at different times. (bottom) The steady-state, vertically integrated conversion from potential energy to eddy kinetic energy 
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(top) Initial instability growth phase in each reference experiment, as reflected in the surface θ field. Note the two figures are at different times. (bottom) The steady-state, vertically integrated conversion from potential energy to eddy kinetic energy
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
(top) Initial instability growth phase in each reference experiment, as reflected in the surface θ field. Note the two figures are at different times. (bottom) The steady-state, vertically integrated conversion from potential energy to eddy kinetic energy
Citation: Journal of Physical Oceanography 44, 8; 10.1175/JPO-D-14-0014.1
In the steady, equilibrated state, the source for eddy kinetic energy is given by the conversion term 
As the eddies equilibrate in the ridge case, there is an additional positive feedback that enhances their local growth; the poleward heat transport by eddies restratifies the interior, reducing the vertical extent of the zonal shear and thus the baroclinic component of the mean eastward zonal flow, proportional to h. This process further slows down the mean flow, reducing the eastward propagation of eddies and allowing continued extraction of mean flow energy into the eddy component.
7. Discussion and conclusions
We have explored the equilibration of an idealized baroclinic current with and without a topographic ridge, with the goal of understanding how zonal asymmetry affects the baroclinic equilibration process. In our simplified experiments, in which the interior of the ocean is quasi adiabatic, the thermocline depth is determined by the competition between poleward cross-frontal heat transport by the geostrophic eddies and the equatorward heat transport by the Ekman circulation. We find that, with localized topography, the eddy field accomplishes the same cross-frontal heat transport as in the flat case, but over a shallower layer and a narrower horizontal region. In this sense the geostrophic turbulence is “more efficient” with a ridge. A simple two-layer QG model partially explains the mechanism for this enhancement: the presence of a standing wave leads to 1) a stronger frontal temperature gradient and 2) increased arclength of time-mean temperature contours. Both of these factors allow the same amount of heat to be transported in a shallower layer. By solving for the standing wave amplitude, the QG model makes a quantitative prediction for the enhancement factor based solely on the external parameters.
However, the picture is complicated by differences in transient eddy behavior. Overall, the transient eddy diffusivity is weaker in the presence of the ridge; the cross-frontal eddy flux is concentrated in a narrow storm track and suppressed elsewhere. Also, the localization itself increases as a function of the winds. An explanation for these differences is in the baroclinic instability mechanism generating transient eddies: global eddy growth and equilibration versus a local growth. The geostrophic turbulence of the zonally symmetric, flat-bottomed channel can be viewed as a finite-amplitude equilibration of the classic global (or convective) baroclinic instability problems posed by Charney (1947) or Phillips (1951). Instead, the ridge experiments illustrate the nonlinear equilibration of local (or absolute) instability discussed by Pierrehumbert (1984), where eddy growth is suppressed away from the localized region of enhanced baroclinicity. In the local instability problem, the growth rate of eddies depends not only on the local baroclinic shear, but also on the vertically averaged zonal flow; a fast, vertically averaged mean flow sweeps the disturbances away from the region of baroclinicity before they can extract energy.
These considerations suggest why eddy fluxes in the storm-track region are exceedingly difficult to parameterize using existing frameworks (Hallberg and Gnanadesikan 2001, 2006). The emergence of eddies from local (or absolute) rather than global (convective) instability indicates that any parameterization of the eddy heat transport would have to take into account not just the local baroclinicity (i.e., shear) and stratification, but also the vertically averaged mean velocity, since this is an important parameter for absolute growth (Pierrehumbert 1984). Furthermore, the suppression of divergent eddy heat fluxes away from the ridge, together with the fact that the maximum eddy flux and mean gradient are not collocated, indicates that eddy generation and dissipation are nonlocal in space, as has been noted in western boundary current regions (Wilson and Williams 2004; Grooms et al. 2013). The inability of existing parameterizations to account for local instability and nonlocal eddy life cycles constitutes the main obstacle toward a more complete theory of baroclinic equilibration in the presence of large topography and the more general problem of inhomogenous geostrophic turbulence.
Acknowledgments
The manuscript was greatly improved thanks to input by Andrew Thompson, Andrew Hogg, and an anonymous reviewer. Support by the Office of Science (BER), U.S. Department of Energy, Grant DE-SC0005100 is gratefully acknowledged.
APPENDIX
An Alternative Derivation of (38)
REFERENCES
Abernathey, R., J. Marshall, and D. Ferreira, 2011: The dependence of Southern Ocean meridional overturning on wind stress. J. Phys. Oceanogr., 41, 2261–2278, doi:10.1175/JPO-D-11-023.1.
Berloff, P., I. Kamenkovich, and J. Pedlosky, 2009: A mechanism of formation of multiple zonal jets in the oceans. J. Fluid Mech., 628, 395–425, doi:10.1017/S0022112009006375.
Bishop, S. P., D. R. Watts, and K. A. Donohue, 2013: Divergent eddy heat fluxes in the Kuroshio extension at 144°–148°E. Part I: Mean structure. J. Phys. Oceanogr., 43, 1533–1550, doi:10.1175/JPO-D-12-0221.1.
Cessi, P., 2008: An energy-constrained parameterization of eddy buoyancy flux. J. Phys. Oceanogr., 38, 1807–1820, doi:10.1175/2007JPO3812.1.
Cessi, P., W. R. Young, and J. A. Polton, 2006: Control of large-scale heat transport by small-scale mixing. J. Phys. Oceanogr., 36, 1877–1895, doi:10.1175/JPO2947.1.
Charney, J. G., 1947: The dynamics of long waves in a baroclinic westerly current. J. Meteor., 4, 136–162, doi:10.1175/1520-0469(1947)004<0136:TDOLWI>2.0.CO;2.
Charney, J. G., and J. D. DeVore, 1979: Multiple flow equilibria in the atmosphere and blocking. J. Atmos. Sci., 36, 1205–1216, doi:10.1175/1520-0469(1979)036<1205:MFEITA>2.0.CO;2.
Charney, J. G., and D. M. Straus, 1980: Form-drag instability, multiple equilibria and propagating planetary waves in baroclinic, orographically forced, planetary wave systems. J. Atmos. Sci., 37, 1157–1176, doi:10.1175/1520-0469(1980)037<1157:FDIMEA>2.0.CO;2.
Chen, C., and I. Kamenkovich, 2013: Effects of topography on baroclinic instability. J. Phys. Oceanogr., 43, 790–804, doi:10.1175/JPO-D-12-0145.1.
de Szoeke, R. A., and M. D. Levine, 1981: The advective flux of heat by mean geostrophic motions in the Southern Ocean. Deep-Sea Res., 28A, 1057–1085, doi:10.1016/0198-0149(81)90048-0.
Dufour, C. O., J. Le Sommer, J. D. Zika, M. Gehlen, J. C. Orr, P. Mathiot, and B. Barnier, 2012: Standing and transient eddies in the response of the Southern Ocean meridional overturning to the southern annular mode. J. Climate, 25, 6958–6974, doi:10.1175/JCLI-D-11-00309.1.
Farneti, R., T. L. Delworth, A. J. Rosati, S. M. Griffies, and F. Zeng, 2010: The role of mesoscale eddies in the rectification of the Southern Ocean response to climate change. J. Phys. Oceanogr., 40, 1539–1558, doi:10.1175/2010JPO4353.1.
Fox-Kemper, B., , R. Ferrari, and J. Pedlosky, 2003: On the indeterminacy of rotational and divergent eddy fluxes. J. Phys. Oceanogr., 33, 478–483, doi:10.1175/1520-0485(2003)033<0478:OTIORA>2.0.CO;2.
Gent, P., and J. McWilliams, 1990: Isopycnal mixing in ocean circulation models. J. Phys. Oceanogr., 20, 150–155, doi:10.1175/1520-0485(1990)020<0150:IMIOCM>2.0.CO;2.
Gnanadesikan, A., 1999: A simple predictive model for the structure of the oceanic pycnocline. Science, 283, 2077–2079, doi:10.1126/science.283.5410.2077.
Gnanadesikan, A., A. M. de Boer, and B. K. Mignone, 2007: A simple theory of the pycnocline and overturning revisited. Ocean Circulation: Mechanisms and Impacts, Geophys. Monogr., Vol. 173, Amer. Geophys. Union, 19–32.
Green, J. S. A., 1970: Transfer properties of the large-scale eddies and the general circulation of the atmosphere. Quart. J. Roy. Meteor. Soc., 96, 157–185, doi:10.1002/qj.49709640802.
Grooms, I., L. Nadeau, and S. Smith, 2013: Mesoscale eddy energy locality in an idealized ocean model. J. Phys. Oceanogr., 43, 1911–1923, doi:10.1175/JPO-D-13-036.1.
Hallberg, R., and A. Gnanadesikan, 2001: An exploration of the role of transient eddies in determining the transport of a zonally reentrant current. J. Phys. Oceanogr., 31, 3312–3330, doi:10.1175/1520-0485(2001)031<3312:AEOTRO>2.0.CO;2.
Hallberg, R., and A. Gnanadesikan, 2006: The role of eddies in determining the structure and response of the wind-driven Southern Hemisphere overturning: Results from the Modeling Eddies in the Southern Ocean (MESO) project. J. Phys. Oceanogr., 36, 2232–2252, doi:10.1175/JPO2980.1.
Haney, R. L., 1971: Surface thermal boundary condition for ocean circulation models. J. Phys. Oceanogr., 1, 241–248, doi:10.1175/1520-0485(1971)001<0241:STBCFO>2.0.CO;2.
Hart, J. E., 1979: Barotropic quasi-geostrophic flow over anisotropic mountains. J. Atmos. Sci., 36, 1736–1746, doi:10.1175/1520-0469(1979)036<1736:BQGFOA>2.0.CO;2.
Held, I. M., 1999: The macroturbulence of the troposphere. Tellus,51A, 59–70, doi:10.1034/j.1600-0870.1999.t01-1-00006.x.
Held, I. M., and M. Ting, 1990: Orographic versus thermal forcing of stationary waves: The importance of the mean low-level wind. J. Atmos. Sci., 47, 495–500, doi:10.1175/1520-0469(1990)047<0495:OVTFOS>2.0.CO;2.
Held, I. M., and V. D. Larichev, 1996: A scaling theory for horizontally homogeneous, baroclinically unstable flow on a beta plane. J. Atmos. Sci., 53, 946–953, doi:10.1175/1520-0469(1996)053<0946:ASTFHH>2.0.CO;2.
Held, I. M., R. L. Panetta, and R. T. Pierrehumbert, 1985: Stationary external Rossby waves in vertical shear. J. Atmos. Sci., 42, 865–883, doi:10.1175/1520-0469(1985)042<0865:SERWIV>2.0.CO;2.
Henning, C. C., and G. K. Vallis, 2005: The effects of mesoscale eddies on the stratification and transport of an ocean with a circumpolar channel. J. Phys. Oceanogr., 35, 880–897, doi:10.1175/JPO2727.1.
Hill, C., D. Ferreira, J.-M. Campin, J. Marshall, R. Abernathey, and N. Barrier, 2012: Controlling spurious diapycnal mixing in eddy-resolving height-coordinate ocean models—Insights from virtual deliberate tracer release experiments. Ocean Modell., 45-46, 14–26, doi:10.1016/j.ocemod.2011.12.001.
Hogg, A. M., M. P. Meredith, J. R. Blundell, and C. Wilson, 2008: Eddy heat flux in the Southern Ocean: Response to variable wind forcing. J. Climate, 21, 608–621, doi:10.1175/2007JCLI1925.1.
Illari, L., and J. C. Marshall, 1983: On the interpretation of eddy fluxes during a blocking episode. J. Atmos. Sci., 40, 2232–2242, doi:10.1175/1520-0469(1983)040<2232:OTIOEF>2.0.CO;2.
Jansen, M., and R. Ferrari, 2012: Macroturbulent equilibration in a thermally forced primitive equation system. J. Atmos. Sci., 69, 695–713, doi:10.1175/JAS-D-11-041.1.
Jayne, S. R., and J. Marotzke, 2002: The oceanic eddy heat transport. J. Phys. Oceanogr., 32, 3328–3345, doi:10.1175/1520-0485(2002)032<3328:TOEHT>2.0.CO;2.
Johnson, G. C., and H. L. Bryden, 1989: On the size of the Antarctic Circumpolar Current. Deep-Sea Res., 36, 39–53, doi:10.1016/0198-0149(89)90017-4.
Kamenkovich, I., and T. Radko, 2011: Role of the Southern Ocean in setting the Atlantic stratification and meridional overturning circulation. J. Mar. Res., 69, 277–308, doi:10.1357/002224011798765286.
Karsten, R., H. Jones, and J. Marshall, 2002: The role of eddy transfer in setting the stratification and transport of a circumpolar current. J. Phys. Oceanogr., 32, 39–54, doi:10.1175/1520-0485(2002)032<0039:TROETI>2.0.CO;2.
Kuo, A., R. A. Plumb, and J. Marshall, 2005: Transformed Eulerian-mean theory. Part II: Potential vorticity homogenization and equilibrium of a wind- and buoyancy-driven zonal flow. J. Phys. Oceanogr., 35, 175–187, doi:10.1175/JPO-2670.1.
Large, W. G., J. C. McWilliams, and S. C. Doney, 1994: Oceanic vertical mixing: A review and a model with a nonlocal boundary layer parameterization. Rev. Geophys., 32, 363–403, doi:10.1029/94RG01872.
MacCready, P., and P. B. Rhines, 2001: Meridional transport across a zonal channel: Topographic localization. J. Phys. Oceanogr., 31, 1427–1439, doi:10.1175/1520-0485(2001)031<1427:MTAAZC>2.0.CO;2.
Marshall, G., 2003: Trends in the southern annular mode from observations and reanalyses. J. Climate, 16, 4134–4144, doi:10.1175/1520-0442(2003)016<4134:TITSAM>2.0.CO;2.
Marshall, J., and G. Shutts, 1981: A note on rotational and divergent eddy fluxes. J. Phys. Oceanogr., 11, 1677–1681, doi:10.1175/1520-0485(1981)011<1677:ANORAD>2.0.CO;2.
Marshall, J., and T. Radko, 2003: Residual mean solutions for the Antarctic Circumpolar Current and its associated overturning circulation. J. Phys. Oceanogr., 33, 2341–2354, doi:10.1175/1520-0485(2003)033<2341:RSFTAC>2.0.CO;2.
Marshall, J., D. Olbers, H. Ross, and D. Wolf-Gladrow, 1993: Potential vorticity constraints on the dynamics and hydrography of the Southern Ocean. J. Phys. Oceanogr., 23, 465–487, doi:10.1175/1520-0485(1993)023<0465:PVCOTD>2.0.CO;2.
Marshall, J., A. Adcroft, C. Hill, L. Perelman, and C. Heisey, 1997a: A finite-volume, incompressible Navier Stokes model for studies of the ocean on parallel computers. J. Geophys. Res., 102, 5753–5766, doi:10.1029/96JC02775.
Marshall, J., C. Hill, L. Perelman, and A. Adcroft, 1997b: Hydrostatic, quasi-hystrostatic, and non-hydrostatic ocean modeling. J. Geophys. Res., 102, 5733–5752, doi:10.1029/96JC02776.
Mazloff, M., P. Heimbach, and C. Wunsch, 2010: An eddy-permitting Southern Ocean state estimate. J. Phys. Oceanogr., 40, 880–899, doi:10.1175/2009JPO4236.1.
Meredith, M. P., and A. M. Hogg, 2006: Circumpolar response of Southern Ocean eddy activity to a change in the southern annular mode. Geophys. Res. Lett.,33, L16608, doi:10.1029/2006GL026499.
Meredith, M. P., A. C. Naveira Garabato, A. M. Hogg, and R. Farneti, 2012: Sensitivity of the overturning circulation in the Southern Ocean to decadal changes in wind forcing. J. Phys. Oceanogr., 42, 99–110, doi:10.1175/2011JCLI4204.1.
Merkine, L.-O., 1977: Convective and absolute instability of baroclinic eddies. Geophys. Astrophys. Fluid Dyn., 9, 129–157, doi:10.1080/03091927708242322.
Morrison, A. K., and A. M. Hogg, 2013: On the relationship between Southern Ocean overturning and ACC transport. J. Phys. Oceanogr., 43, 140–148, doi:10.1175/JPO-D-12-057.1.
Munday, D. R., H. L. Johnson, and D. P. Marshall, 2013: Eddy saturation of equilibrated circumpolar currents. J. Phys. Oceanogr., 43, 507–532, doi:10.1175/JPO-D-12-095.1.
Munk, W., and E. Palmén, 1951: Note on the dynamics of the Antarctic Circumpolar Current. Tellus, 3, 53–55, doi:10.1111/j.2153-3490.1951.tb00776.x.
Naveira-Garabato, A. R., R. Ferrari, and K. Polzin, 2011: Eddy stirring in the Southern Ocean. J. Geophys. Res.,116, C09019, doi:10.1029/2010JC006818.
Nikurashin, M., and G. Vallis, 2012: A theory of the interhemispheric meridional overturning circulation and associated stratification. J. Phys. Oceanogr., 42, 1652–1667, doi:10.1175/JPO-D-11-0189.1.
Olbers, D., 1998: Comments on “On the obscurantist physics of ‘form drag’ in theorizing about the circumpolar current.” J. Phys. Oceanogr., 28, 1647–1655, doi:10.1175/1520-0485(1998)028<1647:COOTOP>2.0.CO;2.
Pedlosky, J., 1987: Geophysical Fluid Dynamics. 2nd ed. Springer-Verlag, 710 pp.
Peixóto, J. P., and A. H. Oort, 1992: Physics of Climate. American Institute of Physics, 520 pp.
Phillips, N. A., 1951: A simple three-dimensional model for the study of large-scale extratropical flow patterns. J. Meteor., 8, 381–393, doi:10.1175/1520-0469(1951)008<0381:ASTDMF>2.0.CO;2.
Pierrehumbert, R. T., 1984: Local and global baroclinic instability of zonally varying flow. J. Atmos. Sci., 41, 2141–2163, doi:10.1175/1520-0469(1984)041<2141:LAGBIO>2.0.CO;2.
Prather, M. J., 1986: Numerical advection by conservation of second-order moments. J. Geophys. Res., 91, 6671–6681, doi:10.1029/JD091iD06p06671.
Schneider, T., 2006: The general circulation of the atmosphere. Annu. Rev. Earth Planet. Sci., 34, 655–688, doi:10.1146/annurev.earth.34.031405.125144.
Shakespeare, C. J., and A. M. Hogg, 2012: An analytical model of the response of the meridional overturning circulation to changes in wind and buoyancy forcing. J. Phys. Oceanogr., 42, 1270–1287, doi:10.1175/JPO-D-11-0198.1.
Speer, K., S. Rintoul, and B. Sloyan, 2000: The diabatic Deacon cell. J. Phys. Oceanogr., 30, 3212–3223, doi:10.1175/1520-0485(2000)030<3212:TDDC>2.0.CO;2.
Stone, P. H., 1972: A simplified radiative-dynamical model for the static stability of rotating atmospheres. J. Atmos. Sci., 29, 405–417, doi:10.1175/1520-0469(1972)029<0405:ASRDMF>2.0.CO;2.
Straub, D., 1993: On the transport and angular momentum balance of channel models of the Antarctic Circumpolar Current. J. Phys. Oceanogr., 23, 776–783, doi:10.1175/1520-0485(1993)023<0776:OTTAAM>2.0.CO;2.
Thompson, A. F., 2010: Jet formation and evolution in baroclinic turbulence with simple topography. J. Phys. Oceanogr., 40, 257–274, doi:10.1175/2009JPO4218.1.
Thompson, A. F., and W. R. Young, 2006: Scaling baroclinic eddy fluxes: Vortices and energy balance. J. Phys. Oceanogr., 36, 720–738, doi:10.1175/JPO2874.1.
Thompson, A. F., and J.-B. Sallée, 2012: Jets and topography: Jet transitions and the impact on transport in the Antarctic Circumpolar Current. J. Phys. Oceanogr., 42, 956–972, doi:10.1175/JPO-D-11-0135.1.
Toggweiler, J. R., 2009: Shifting westerlies. Science, 323, 1434–1435, doi:10.1126/science.1169823.
Toggweiler, J. R., and B. Samuels, 1995: Effect of Drake Passage on the global thermohaline circulation. Deep-Sea Res. I, 42, 477–500, doi:10.1016/0967-0637(95)00012-U.
Toggweiler, J. R., and J. Russell, 2008: Ocean circulation in a warming climate. Nature, 451, 286–288, doi:10.1038/nature06590.
Treguier, A. M., and J. C. McWilliams, 1990: Topographic influences on wind-driven, stratified flow in a beta-plane channel: An idealized model for the Antarctic Circumpolar Current. J. Phys. Oceanogr., 20, 321–343, doi:10.1175/1520-0485(1990)020<0321:TIOWDS>2.0.CO;2.
Treguier, A. M., J. Le Sommer, and J. M. Molines, 2010: Response of the Southern Ocean to the southern annular mode: Interannual variability and multidecadal trend. J. Phys. Oceanogr., 40, 1659–1668, doi:10.1175/2010JPO4364.1.
Viebahn, J., and C. Eden, 2010: Toward the impact of eddies on the response of the Southern Ocean to climate change. Ocean Modell., 34, 150–165, doi:10.1016/j.ocemod.2010.05.005.
Viebahn, J., and C. Eden, 2012: Standing eddies in the meridional overturning circulation. J. Phys. Oceanogr., 42, 1486–1508, doi:10.1175/JPO-D-11-087.1.
Visbeck, M.,