Axisymmetric stability of the flow between two exactly counter-rotating disks with large aspect ratio

We study the first bifurcation in the axisymmetric flow between two exactly counter-rotating disks with very large aspect ratio $ \Gamma\,{\equiv}\, R/H$, where $R$ is the disk radius and $2 H$ is the inter-disk spacing. The scaling law for the critical Reynolds number is found to be $\Rey_c \propto...

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Bibliographic Details
Published in:Journal of fluid mechanics 2006-01, Vol.546 (1), p.193-202
Main Authors: WITKOWSKI, L. MARTIN, DELBENDE, I., WALKER, J. S., QUÉRÉ, P. LE
Format: Article
Language:English
Subjects:
Base flow
Exact sciences and technology
Fluid dynamics
Fluid mechanics
Fundamental areas of phenomenology (including applications)
Hydrodynamic stability
Instability of shear flows
Kinematic viscosity
Mechanics
Nonlinearity (including bifurcation theory)
Physics
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Summary:We study the first bifurcation in the axisymmetric flow between two exactly counter-rotating disks with very large aspect ratio $ \Gamma\,{\equiv}\, R/H$, where $R$ is the disk radius and $2 H$ is the inter-disk spacing. The scaling law for the critical Reynolds number is found to be $\Rey_c \propto \Gamma^{-1/2}$, with $\Rey \,{\equiv}\, \Omega H^2/\nu$, $\Omega$ being the magnitude of the angular velocity and $\nu$ the kinematic viscosity. An asymptotic analysis for large $\Gamma$ is developed, in which curvature is neglected, but the centrifugal acceleration term is retained. The Navier–Stokes equations then reduce to leading order to those in a Cartesian frame, and the axisymmetric base flow to a parallel flow. This allows us locally to use a Fourier decomposition along the radial direction. In this framework, we explain the physical mechanism of the instability invoking the linear azimuthal velocity profile and the effect of centrifugal acceleration.
ISSN:0022-1120
1469-7645
DOI:10.1017/S0022112005007433