Turbulent diffusion in the geostrophic 
inverse cascade

Smith, K. Shafer; Boccaletti, Giulio; Henning, Cara; Marinov, I.; Tam, Chi‐Yung; Held, Isaac M.; Vallis, Geoffrey K.

doi:10.1017/s0022112002001763

Cited by 168 publications

(196 citation statements)

References 39 publications

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“…This argument is for inviscid unforced decaying turbulence, and it was extended to general α by Smith et al (2002). Global conservation together with the assumption that the energy and enstrophy distributions broaden around the initial wavenumber allow one to prove that the energy and enstrophy centroid wavenumbers move to larger and smaller scales, respectively, for α > 0.…”

Section: Arguments For Cascade Directionsmentioning

confidence: 93%

“…Shallow-water quasigeostrophic dynamics in the limit of strong rotation, i.e. the asymptotic model limit of the Charney-Hasegawa-Mima equation (Larichev & McWilliams 1991;Iwayama, Shepherd & Watanabe 2002) corresponds to α = −2 (Smith et al 2002). Surface quasigeostrophic (SQG) dynamics, a simplified model for edge waves on the tropopause or temperature advection near the Earth's surface (Blumen 1978;Held et al 1995), is given by α = 1, and 2D Navier-Stokes dynamics corresponds to α = 2, as noted above.…”

Section: Introductionmentioning

confidence: 99%

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Spectral non-locality, absolute equilibria and Kraichnan–Leith–Batchelor phenomenology in two-dimensional turbulent energy cascades

Burgess

Shepherd

2013

J. Fluid Mech.

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We study the degree to which Kraichnan–Leith–Batchelor (KLB) phenomenology describes two-dimensional energy cascades in $\alpha $ turbulence, governed by $\partial \theta / \partial t+ J(\psi , \theta )= \nu {\nabla }^{2} \theta + f$, where $\theta = {(- \Delta )}^{\alpha / 2} \psi $ is generalized vorticity, and $\hat {\psi } (\boldsymbol{k})= {k}^{- \alpha } \hat {\theta } (\boldsymbol{k})$ in Fourier space. These models differ in spectral non-locality, and include surface quasigeostrophic flow ($\alpha = 1$), regular two-dimensional flow ($\alpha = 2$) and rotating shallow flow ($\alpha = 3$), which is the isotropic limit of a mantle convection model. We re-examine arguments for dual inverse energy and direct enstrophy cascades, including Fjørtoft analysis, which we extend to general $\alpha $, and point out their limitations. Using an $\alpha $-dependent eddy-damped quasinormal Markovian (EDQNM) closure, we seek self-similar inertial range solutions and study their characteristics. Our present focus is not on coherent structures, which the EDQNM filters out, but on any self-similar and approximately Gaussian turbulent component that may exist in the flow and be described by KLB phenomenology. For this, the EDQNM is an appropriate tool. Non-local triads contribute increasingly to the energy flux as $\alpha $ increases. More importantly, the energy cascade is downscale in the self-similar inertial range for $2. 5\lt \alpha \lt 10$. At $\alpha = 2. 5$ and $\alpha = 10$, the KLB spectra correspond, respectively, to enstrophy and energy equipartition, and the triad energy transfers and flux vanish identically. Eddy turnover time and strain rate arguments suggest the inverse energy cascade should obey KLB phenomenology and be self-similar for $\alpha \lt 4$. However, downscale energy flux in the EDQNM self-similar inertial range for $\alpha \gt 2. 5$ leads us to predict that any inverse cascade for $\alpha \geq 2. 5$ will not exhibit KLB phenomenology, and specifically the KLB energy spectrum. Numerical simulations confirm this: the inverse cascade energy spectrum for $\alpha \geq 2. 5$ is significantly steeper than the KLB prediction, while for $\alpha \lt 2. 5$ we obtain the KLB spectrum.

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Section: Arguments For Cascade Directionsmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Spectral non-locality, absolute equilibria and Kraichnan–Leith–Batchelor phenomenology in two-dimensional turbulent energy cascades

Burgess

Shepherd

2013

J. Fluid Mech.

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“…The effects of drag on geophysical turbulence have been studied extensively using two-dimensional and shallowwater models (Danilov and Gurarie 2002;Smith et al 2002;Galperin et al 2006;Scott and Dritschel 2013) and in the quasigeostrophic two-layer model (Thompson and Young 2007). In general, drag removes energy from the system and contributes to halting the inverse cascade (Vallis 2006).…”

mentioning

confidence: 99%

Scaling of Off-Equatorial Jets in Giant Planet Atmospheres

Liu

Schneider

2015

Journal of the Atmospheric Sciences

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In the off-equatorial region of Jupiter's and Saturn's atmospheres, baroclinic eddies transport angular momentum out of retrograde and into prograde jets. In a statistically steady state, this angular momentum transfer by eddies must be balanced by dissipation, likely produced by magnetohydrodynamic (MHD) drag in the planetary interior. This paper examines systematically how an idealized representation of this drag in a general circulation model (GCM) of the upper atmosphere of giant planets modifies jet characteristics, the angular momentum budget, and the energy budget.In the GCM, Rayleigh drag at an artificial lower boundary (with mean pressure of 3 bar) is used as a simple representation of the MHD drag that the flow on giant planets experiences at depth. As the drag coefficient decreases, the eddy length scale and eddy kinetic energy increase, as they do in studies of two-dimensional turbulence. Off-equatorial jets become wider and stronger, with increased interjet spacing. Coherent vortices also become more prevalent. Generally, the jet width scales with the Rhines scale, which is of similar magnitude as the Rossby radius in the simulations. The jet strength increases primarily through strengthening of the barotropic component, which increases as the drag coefficient decreases because the overall kinetic energy dissipation remains roughly constant. The overall kinetic energy dissipation remains roughly constant presumably because it is controlled by baroclinic conversion of potential to kinetic energy in the upper troposphere, which is mainly determined by the differential solar radiation and is only weakly dependent on bottom drag and barotropic flow variations.For Jupiter and Saturn, these results suggest that the wider and stronger jets on Saturn may arise because the MHD drag on Saturn is weaker than on Jupiter, while the thermodynamic efficiencies of the atmospheres are not sensitive to the drag parameters.

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“…We also use double the spatial resolution (256 2 ) and twice the Rayleigh drag coefficient [0.6 in units of inverse model time; the eddy time scale based on enstrophy defined as in O'Gorman and Schneider (2006) is 0.78]. The smoothing filter F is applied to both the vorticity and the moisture fields and is only active at k $ 50 (Smith et al 2002;O'Gorman and Schneider 2006). The kinetic energy spectrum peaks at the forcing wavenumbers and displays a power-law range at higher wavenumbers that is roughly consistent with the steepness of the spectrum found in observations of the troposphere at large scales (Boer and Shepherd 1983); however, the tropospheric spectrum results from a more complicated range of processes than just the nonlinear eddy-eddy interactions that are important in the turbulent flow considered here (Schneider and Walker 2006;O'Gorman and Schneider 2007).…”

Section: B Turbulent Advectionmentioning

confidence: 99%

The Relative Humidity in an Isentropic Advection–Condensation Model: Limited Poleward Influence and Properties of Subtropical Minima

O’Gorman

Lamquin

Schneider

et al. 2011

Journal of the Atmospheric Sciences

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An idealized model of advection and condensation of water vapor is considered as a representation of processes influencing the humidity distribution along isentropic surfaces in the free troposphere. Results are presented for how the mean relative humidity distribution varies in response to changes in the distribution of saturation specific humidity and in the amplitude of a tropical moisture source. Changes in the tropical moisture source are found to have little effect on the relative humidity poleward of the subtropical minima, suggesting a lack of poleward influence despite much greater water vapor concentrations at lower latitudes. The subtropical minima in relative humidity are found to be located just equatorward of the inflection points of the saturation specific humidity profile along the isentropic surface. The degree of mean subsaturation is found to vary with the magnitude of the meridional gradient of saturation specific humidity when other parameters are held fixed.The atmospheric relevance of these results is investigated by comparison with the positions of the relative humidity minima in reanalysis data and by examining poleward influence of relative humidity in simulations with an idealized general circulation model. It is suggested that the limited poleward influence of relative humidity may constrain the propagation of errors in simulated humidity fields.

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Turbulent diffusion in the geostrophic inverse cascade

Cited by 168 publications

References 39 publications

Spectral non-locality, absolute equilibria and Kraichnan–Leith–Batchelor phenomenology in two-dimensional turbulent energy cascades

Spectral non-locality, absolute equilibria and Kraichnan–Leith–Batchelor phenomenology in two-dimensional turbulent energy cascades

Scaling of Off-Equatorial Jets in Giant Planet Atmospheres

The Relative Humidity in an Isentropic Advection–Condensation Model: Limited Poleward Influence and Properties of Subtropical Minima

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