Eckhaus-like instability of large scale coherent structures in a fully turbulent von K\'arm\'an flow

Abstract

The notion of instability of a turbulent flow is introduced in the case of a von K\'arm\'an flow thanks to the monitoring of the spatio-temporal spectrum of the velocity fluctuations, combined with projection onto suitable Beltrami modes. It is shown that the large scale coherent fluctuations of the flow obeys a sequence of Eckhaus instabilities when the Reynolds number Re is varied from 102 to 106. This sequence results in modulations of increasing azimuthal wavenumber. The basic state is the laminar or time-averaged flow at an arbitrary Re, which is axi-symmetric, i.e. with a 0 azimuthal wavenumber. Increasing Re leads to non-axisymmetric modulations with increasing azimuthal wavenumber from 1 to 3. These modulations are found to rotate in the azimuthal direction. However no clear rotation frequency can be established until Re≈ 4× 103. Above, they become periodic with an increasing frequency. We finally show that these modulations are connected with the coherent structures of the mixing shear layer. The implication of these findings for the turbulence parametrization is discussed. Especially, they may explain why simple eddy viscosity models are able to capture complex turbulent flow dynamics.