The structure of zonal jets in geostrophic turbulence

Scott, R. K.; Dritschel, David G.

doi:10.1017/jfm.2012.410

Cited by 75 publications

(119 citation statements)

References 27 publications

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“…This competition between thermal forcing and baroclinic instability gives rise to the formation of baroclinic jets and, in extreme cases, to stepped PV profiles or 'staircases'. Such staircase formation has already been demonstrated in the single-layer barotropic context (see Dritschel & McIntyre (2008) and Scott & Dritschel (2012)). Additionally, in the present model small-scale stochastic forcing is imposed, crudely mimicking convective processes.…”

Section: Introductionsupporting

confidence: 52%

“…The jets form through inhomogeneous potential vorticity mixing (Dritschel & McIntyre 2008;Scott & Dritschel 2012), in which potential vorticity is nearly homogenised in bands, but between which the potential vorticity abruptly jumps, forming a 'staircase' profile. Each jump is associated with a jet, eastward in the upper layer and westward in the lower layer, a direct effect of potential vorticity inversion (Dritschel & McIntyre 2008).…”

Section: Discussionmentioning

confidence: 99%

“…In the lower layer, by contrast, there are three bands of nearly homogeneous PV separated by two westward jets. As discussed in Dritschel & McIntyre (2008) and Scott & Dritschel (2012) in the context of a single-layer model, the 'equivalent latitude' PV profile y e (q) is particularly useful for identifying jets, here seen by the nearly flat portions of the curves shown in the right panels of these figures. The formation of a staircase profile in y e (q) indicates the presence of homogeneous regions (dy e /dq → ∞) and jets (dy e /dq → 0).…”

Section: A Characteristic Simulationmentioning

confidence: 97%

“…Instead, part of this decay must be due to inhomogeneous turbulent mixing, constrained by the mean PV gradient in each layer. The mixing acts to homogenise PV and sharpen jets, processes which are only enhanced by non-zonal variations (Dritschel & McIntyre 2008;Scott & Dritschel 2012). The mixing continues until most of the eddy energy (principally at higher wavenumbers where thermal damping is weak) is exhausted and converted into jets (qualitatively this is the argument behind the Rhines scale L Rh = U/β, where U characterises the eddy velocities and β is the background PV gradient, see Rhines (1975)).…”

Section: Focus On a Turbulent Phasementioning

confidence: 99%

“…Restoration of a linear slope would not have this effect, as a linear slope only generates a baroclinic flow, by construction. Instead, it must be that the eddying motions present even during quiescent phases continue to provide inhomogeneous PV mixing, maintaining sharp jets (Dritschel & McIntyre 2008;Scott & Dritschel 2012). These jets project on both barotropic and baroclinic modes, unlike the initial vertical shear flow.…”

Section: Energy Transfersmentioning

confidence: 99%

See 4 more Smart Citations

On the energetics of a two-layer baroclinic flow

Jougla

Dritschel

2017

J. Fluid Mech.

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The formation, evolution and co-existence of jets and vortices in turbulent planetary atmospheres is examined using a two-layer quasi-geostrophic β-channel shallow water model. The study in particular focuses on the vertical structure of jets. Following Panetta & Held (1988), a vertical shear arising from latitudinal heating variations is imposed on the flow and maintained by thermal damping. Idealised convection between the upper and lower layers is implemented by adding cyclonic/anti-cyclonic pairs, called hetons, to the flow, though the qualitative flow evolution is evidently not sensitive to this or other small-scale stochastic forcing. A very wide range of simulations have been conducted. A characteristic simulation which exhibits alternation between two different phases, quiescent and turbulent, is examined in detail. We study the energy transfers between different components and modes, and find the classical picture of barotropic/baroclinic energy transfers to be too simplistic. We also discuss the dependence on thermal damping and on the imposed vertical shear. Both have a strong influence on the flow evolution. Thermal damping is a major factor affecting the stability of the flow while vertical shear controls the number of jets in the domain, qualitatively through the Rhines scale L Rh = U/β.

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Section: Introductionsupporting

confidence: 52%

Section: Discussionmentioning

confidence: 99%

Section: A Characteristic Simulationmentioning

confidence: 97%

Section: Focus On a Turbulent Phasementioning

confidence: 99%

Section: Energy Transfersmentioning

confidence: 99%

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On the energetics of a two-layer baroclinic flow

Jougla

Dritschel

2017

J. Fluid Mech.

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Vertical structure of tropospheric winds on gas giants

Scott

Dunkerton

2017

Geophysical Research Letters

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Zonal mean zonal velocity profiles from cloud‐tracking observations on Jupiter and Saturn are used to infer latitudinal variations of potential temperature consistent with a shear stable potential vorticity distribution. Immediately below the cloud tops, density stratification is weaker on the poleward and stronger on the equatorward flanks of midlatitude jets, while at greater depth the opposite relation holds. Thermal wind balance then yields the associated vertical shears of midlatitude jets in an altitude range bounded above by the cloud tops and bounded below by the level where the latitudinal gradient of static stability changes sign. The inferred vertical shear below the cloud tops is consistent with existing thermal profiling of the upper troposphere. The sense of the associated mean meridional circulation in the upper troposphere is discussed, and expected magnitudes are given based on existing estimates of the radiative timescale on each planet.

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On the equilibration of asymmetric barotropic instability

Harnik

Dritschel

Heifetz

2014

Quart J Royal Meteoro Soc

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The conjunction of turbulence, waves and zonal jets in geophysical flows gives rise to the formation of potential vorticity staircases and to the sharpening of jets by eddies. The effect of eddies on jet structure, however, is fundamentally different if the eddies arise from barotropic rather than from baroclinic instability. As is well known, barotropic instability may occur on zonal jets when there is a reversal of potential vorticity gradients at the jet flanks. In this article we focus on the nonlinear stages of this instability and its eventual saturation. We consider an idealized initial state consisting of an anticyclonic potential vorticity strip sitting in the flanks of an eastward jet. This asymmetric configuration, a generalization of the Rayleigh problem, is one of the simplest barotropic jet configurations which incorporates many fundamental aspects of real flows, including linear instability and its equilibration, nonlinear interactions, scale cascades, vortex dynamics, and jet sharpening. We make use of the simplicity of the problem to conduct an extensive parameter sweep, and develop a theory relating the properties of the equilibrated flow to the initial flow state by considering the marginal stability limit, together with conservation of circulation and wave activity.

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The structure of zonal jets in geostrophic turbulence

Cited by 75 publications

References 27 publications

On the energetics of a two-layer baroclinic flow

On the energetics of a two-layer baroclinic flow

Vertical structure of tropospheric winds on gas giants

On the equilibration of asymmetric barotropic instability

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