Centrifugal instability of Taylor-Couette flow in stratified and diffusive fluids
Abstract
The linear and non-linear dynamics of centrifugal instability in Taylor-Couette flow are investigated when fluids are stably stratified and highly diffusive. One-dimensional local linear stability analysis (LSA) on cylindrical Couette flow confirms that the stabilising role of stratification on centrifugal instability is suppressed by strong thermal diffusion (i.e. low Prandtl number Pr). For Pr1, it is verified that the instability dependence on thermal diffusion and stratification with the non-dimensional Brunt-V\"ais\"al\"a frequency N can be prescribed by a single rescaled parameter PN=N2Pr. From direct numerical simulation (DNS), various non-linear features such as axisymmetric Taylor vortices at saturation, secondary instability leading to non-axisymmetric patterns or transition to chaotic states are investigated for various values of Pr≤1 and the Reynolds number Rei. Two-dimensional bi-global LSA on axisymmetric Taylor vortices, which appear as primary centrifugal instability saturates nonlinearly, is also performed to find the secondary critical Reynolds number Rei,2 at which the Taylor vortices become unstable by non-axisymmetric perturbation. The bi-global LSA reveals that Rei,2 increases (i.e. the onset of secondary instability is delayed) in the range 10-3<Pr<1 at N=1 or as N increases at Pr=0.01. Secondary instability leading to highly non-axisymmetric or irregular chaotic patterns is further investigated by the 3D DNS. The Nusselt number Nu is also computed from the torque at the inner cylinder for various Pr and Rei at N=1 to describe how the angular momentum transfer increases with Rei and how Nu varies differently for saturated and chaotic states.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.