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Linearly forced fluid flow on a rotating sphere

Rohit Supekar, Vili Heinonen, Keaton J. Burns, Jörn Dunkel

2020Journal of Fluid Mechanics14 citationsDOIOpen Access PDF

Abstract

We investigate generalized Navier–Stokes (GNS) equations that couple nonlinear advection with a generic linear instability. This analytically tractable minimal model for fluid flows driven by internal active stresses has recently been shown to permit exact solutions on a stationary two-dimensional sphere. Here, we extend the analysis to linearly driven flows on rotating spheres. We derive exact solutions of the GNS equations corresponding to time-independent zonal jets and superposed westward-propagating Rossby waves, qualitatively similar to those seen in planetary atmospheres. Direct numerical simulations with large rotation rates obtain statistically stationary states close to these exact solutions. The measured phase speeds of waves in the GNS simulations agree with analytical predictions for Rossby waves.

Topics & Concepts

PhysicsRossby numberRossby waveAdvectionClassical mechanicsMechanicsGeophysical fluid dynamicsInstabilityNonlinear systemFlow (mathematics)Exact solutions in general relativitySPHERESRotation (mathematics)MathematicsGeometryTurbulenceAstronomyQuantum mechanicsThermodynamicsAtmospheric sciencesMicro and Nano RoboticsGeomagnetism and Paleomagnetism StudiesAstro and Planetary Science
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