The role of Stewartson and Ekman layers in turbulent rotating Rayleigh–Bénard convection

Kunnen, Rudie; Stevens, Richard J. A. M.; Overkamp, Jim V.; Sun, Chao; Heijst, GertJan F. van; Clercx, Hjh Herman

doi:10.1017/jfm.2011.383

Cited by 64 publications

(121 citation statements)

References 56 publications

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“…11 and 12. At small enough Ro, experiments and direct numerical simulations (DNSs) of the full Navier-Stokes equations (in the Boussinesq approximation) should give similar results as simulations of the asymptotically reduced equations. Up to now, most of the experiments [13][14][15][16][17][18][19][20][21][22][23] and DNSs 16,18,[24][25][26][27] did not reach deep into the rapidly rotating convection regime. The few experimental and numerical studies that entered decisively into this regime 9,[28][29][30] primarily use the overall heat transfer to characterize rapidly rotating Rayleigh-Bénard convection and identify transitions between flow regimes from changes in the heat-flux scaling.…”

Section: Introductionmentioning

confidence: 98%

Exploring the geostrophic regime of rapidly rotating convection with experiments

2017

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Rapidly rotating Rayleigh–Bénard convection is studied using time-resolved particle image velocimetry and three-dimensional particle tracking velocimetry. Approaching the geostrophic regime of rotating convection, where the flow is highly turbulent and at the same time dominated by the Coriolis force, typically requires dedicated setups with either extreme dimensions or troublesome working fluids (e.g., cryogenic helium). In this study, we explore the possibilities of entering the geostrophic regime of rotating convection with classical experimental tools: a table-top conventional convection cell with a height of 0.2 m and water as the working fluid. In order to examine our experimental measurements, we compare the spatial vorticity autocorrelations with the statistics from simulations of geostrophic convection reported earlier in [D. Nieves et al., “Statistical classification of flow morphology in rapidly rotating Rayleigh-Bénard convection,” Phys. Fluids 26, 086602 (2014)]. Our findings show that we have indeed access to the geostrophic convection regime and can observe the signatures of the typical flow features reported in the aforementioned simulations.

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Section: Introductionmentioning

confidence: 98%

Exploring the geostrophic regime of rapidly rotating convection with experiments

2017

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“…Of recent interest in these studies have been transitions between rotationally dominated and nonrotating turbulent states (2-10) and the enhancement of heat transport by rotation (6,8,(11)(12)(13)(14)(15). Numerical simulations of planetary dynamo action by rotating convection also concentrate on fluids with unit order Pr (16).…”

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confidence: 99%

Turbulent convection in liquid metal with and without rotation

King

Aurnou

2013

Proc. Natl. Acad. Sci. U.S.A.

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The magnetic fields of Earth and other planets are generated by turbulent, rotating convection in liquid metal. Liquid metals are peculiar in that they diffuse heat more readily than momentum, quantified by their small Prandtl numbers, Pr = 1. Most analog models of planetary dynamos, however, use moderate Pr fluids, and the systematic influence of reducing Pr is not well understood. We perform rotating Rayleigh-Bénard convection experiments in the liquid metal gallium (Pr = 0:025) over a range of nondimensional buoyancy forcing (Ra) and rotation periods (E). Our primary diagnostic is the efficiency of convective heat transfer (Nu). In general, we find that the convective behavior of liquid metal differs substantially from that of moderate Pr fluids, such as water. In particular, a transition between rotationally constrained and weakly rotating turbulent states is identified, and this transition differs substantially from that observed in moderate Pr fluids. This difference, we hypothesize, may explain the different classes of magnetic fields observed on the Gas and Ice Giant planets, whose dynamo regions consist of Pr < 1 and Pr > 1 fluids, respectively.T he interiors of Earth and other terrestrial bodies, as well as the Gas Giant planets, contain vast oceans of flowing metals. Mixed by turbulent convection as these planets cool, the flowing conductors produce electric currents that maintain planetary magnetic fields. These bodies also rotate, and it is expected that the resulting Coriolis forces strongly influence convective dynamo processes. Beyond linear theory (1), however, not much is known about the dynamics of rotating convection in liquid metal that underlie planetary magnetic field generation.Theory and experiments often focus on a simplified analog of geophysical and astrophysical systems, Rayleigh-Bénard convection (RBC). The RBC system consists of a fluid layer contained between flat, horizontal plates separated by distance h, the bottom of which is warmer than the top by ΔT, and with downward pointing gravity, g. Near the bottom boundary, the fluid warms and expands by a volumetric factor α (per degree kelvin) and similarly cools and contracts near the top boundary, such that the fluid is unstably stratified.Rotating convection is explored by spinning the RBC system about a vertical axis at an angular rate Ω, which is adopted as the reference frame for the model. The fluid dynamics of the system are characterized by three dimensionless parameters. The Prandtl number, Pr ≡ ν=κ, defines the diffusive transport properties of the fluid, where ν and κ are its viscous and thermal diffusivities. The Rayleigh number, Ra ≡ αgΔTh 3 =ðνκÞ, prescribes the magnitude of the buoyancy force. Finally, the rotation period is specified by the Ekman number, E ≡ ν=ð2Ωh 2 Þ. The primary diagnostic used in many convection studies, including this one, is the Nusselt number, which characterizes the efficiency of heat transport by convection as Nu ≡ qh=ðkΔTÞ, where q is total heat flux and k is the fluid's thermal conductivi...

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“…The extreme thinness of the boundary layers poses difficult challenges to the experimental techniques while numerical simulations need to use the largest computers now available to attack this parameter range. Another point deserving investigation is the structure of the boundary layers in the presence of background rotation that introduces the Rossby number as additional input and increases the complexity of the physics with the Ekman and Stewartson layers (Kunnen et al 2011). All these topics are being clarified thanks to the combination of theoretical models, laboratory experiments and numerical simulation all involved in the joint effort to unravel the complex dynamics of the turbulent Rayleigh-Bénard flow.…”

Section: Futurementioning

confidence: 99%

Boundary layer structure in confined turbulent thermal convection

Verzicco

2012

J. Fluid Mech.

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The structure of viscous and thermal boundary layers at the heated and cooled plates in turbulent thermally driven flows are of fundamental importance for heat transfer and its dependence on the thermal forcing (the Rayleigh number Ra in non-dimensional form). The paper by Shi, Emran & Schumacher (J. Fluid Mech., this issue, vol. 706, 2012, pp. 5-33) stresses the deviations of the boundary layer vertical profiles from the Prandtl-Blasius-Pohlhausen theory. Recent papers showing very similar results, in contrast, focus more on the similarities.

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The role of Stewartson and Ekman layers in turbulent rotating Rayleigh–Bénard convection

Cited by 64 publications

References 56 publications

Exploring the geostrophic regime of rapidly rotating convection with experiments

Exploring the geostrophic regime of rapidly rotating convection with experiments

Turbulent convection in liquid metal with and without rotation

Boundary layer structure in confined turbulent thermal convection

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