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Stability of a vortex in radial density stratification: role of wave interactions

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dc.contributor.author Dixit, Harish N
dc.contributor.author Govindarajan, Rama
dc.date.accessioned 2012-03-15T09:21:07Z
dc.date.available 2012-03-15T09:21:07Z
dc.date.issued 2011-07
dc.identifier 0022-1120 en_US
dc.identifier.citation Journal of Fluid Mechanics 679, 582-615 (2011) en_US
dc.identifier.uri https://libjncir.jncasr.ac.in/xmlui/10572/638
dc.description.abstract We study the stability of a vortex in an axisymmetric density distribution. It is shown that a light-cored vortex can be unstable in spite of the 'stable stratification' of density. Using a model flow consisting of step jumps in vorticity and density, we show that a wave interaction mediated by shear is the mechanism for the instability. The requirement is for the density gradient to be placed outside the vortex core but within the critical radius of the Kelvin mode. Conversely, a heavy-cored vortex, found in other studies to be unstable in the centrifugal Rayleigh-Taylor sense, is stabilized when the density jump is placed in this region. Asymptotic solutions at small Atwood number At show growth rates scaling as At(1/3) close to the critical radius, and At(1/2) further away. By considering a family of vorticity and density profiles of progressively increasing smoothness, going from a step to a Gaussian, it is shown that sharp gradients are necessary for the instability of the light-cored vortex, consistent with recent work which found Gaussian profiles to be stable. For sharp gradients, it is argued that wave interaction can be supported due to the presence of quasi-modes. Probably for the first time, a quasi-mode which decays exponentially is shown to interact with a neutral wave to give exponential growth in the combined case. We finally study the nonlinear stages using viscous direct numerical simulations. The initial exponential instability of light-cored vortices is arrested due to a restoring centrifugal buoyancy force, leading to stable non-axisymmetric structures, such as a tripolar state for an azimuthal wavenumber of 2. The study is restricted to two dimensions, and neglects gravity. en_US
dc.description.uri http://dx.doi.org/10.1017/jfm.2011.156 en_US
dc.language.iso en en_US
dc.publisher Cambridge University Press en_US
dc.rights © 2011 Cambridge University Press en_US
dc.subject internal waves en_US
dc.subject vortex instability en_US
dc.subject waves in rotating fluids en_US
dc.subject Rayleigh-Taylor Instability en_US
dc.subject Lamb-Oseen Vortex en_US
dc.subject Shear-Flow en_US
dc.subject Rotating Fluid en_US
dc.subject Boundary-Layer en_US
dc.subject Swirling Flows en_US
dc.subject Rossby Waves en_US
dc.subject Vorticity en_US
dc.subject Resonance en_US
dc.subject Modes en_US
dc.title Stability of a vortex in radial density stratification: role of wave interactions en_US
dc.type Article en_US


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