Stability and turbulent transport in rotating shear flows: prescription from analysis of cylindrical and plane Couette flows data

TL;DR

This paper develops a new prescription for turbulent viscosity in rotating shear flows based on experimental data analysis, applicable to geophysical and astrophysical contexts, and introduces a universal torque decomposition model.

Contribution

It introduces a new set of control parameters and a universal torque decomposition to derive a general turbulent viscosity expression from experimental data.

Findings

Proposes a new control parameter set based on dynamical considerations.

Derives a universal torque decomposition model.

Provides a new turbulent viscosity prescription applicable to rotating shear flows.

Abstract

This paper provides a prescription for the turbulent viscosity in rotating shear flows for use e.g. in geophysical and astrophysical contexts. This prescription is the result of the detailed analysis of the experimental data obtained in several studies of the transition to turbulence and turbulent transport in Taylor-Couette flow. We first introduce a new set of control parameters, based on dynamical rather than geometrical considerations, so that the analysis applies more naturally to rotating shear flows in general and not only to Taylor-Couette flow. We then investigate the transition thresholds in the supercritical and the subcritical regime in order to extract their general dependencies on the control parameters. The inspection of the mean profiles provides us with some general hints on the mean to laminar shear ratio. Then the examination of the torque data allows us to propose a decomposition of the torque dependence on the control parameters in two terms, one completely given by measurements in the case where the outer cylinder is at rest, the other one being a universal function provided here from experimental fits. As a result, we obtain a general expression for the turbulent viscosity and compare it to existing prescription in the literature. Finally, throughout all the paper we discuss the influence of additional effects such as stratification or magnetic fields.