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Competition between Ekman Plumes and Vortex Condensates in Rapidly Rotating Thermal Convection

Andrés J. Aguirre Guzmán, Matteo Madonia, Jonathan Cheng, Rodolfo Ostilla–Mónico, H. J. H. Clercx, Rudie Kunnen

2020Physical Review Letters38 citationsDOIOpen Access PDF

Abstract

We perform direct numerical simulations of rotating Rayleigh-Bénard convection (RRBC) of fluids with low (Pr=0.1) and high (Pr≈5) Prandtl numbers in a horizontally periodic layer with no-slip bottom and top boundaries. No-slip boundaries are known to actively promote the formation of plumelike vertical disturbances, through so-called Ekman pumping, that control the ambient flow at sufficiently high rotation rates. At both Prandtl numbers, we demonstrate the presence of competing large-scale vortices (LSVs) in the bulk. Strong buoyant forcing and rotation foster the quasi-two-dimensional turbulent state of the flow that leads to the upscale transfer of kinetic energy that forms the domain-filling LSV condensate. The Ekman plumes from the boundary layers are sheared apart by the large-scale flow, yet we find that their energy feeds the upscale transfer. Our results of RRBC simulations substantiate the emergence of large-scale flows in nature regardless of the specific details of the boundary conditions.

Topics & Concepts

Prandtl numberEkman layerVortexEkman transportPhysicsMechanicsEkman numberTurbulenceConvectionBoundary layerClassical mechanicsGeologyUpwellingOceanographyFluid Dynamics and Turbulent FlowsPlant Water Relations and Carbon DynamicsFluid Dynamics and Vibration Analysis