Large-scale instabilities of helical flows

Abstract

Large-scale hydrodynamic instabilities of periodic helical flows are investigated using 3D Floquet numerical computations. A minimal three-modes analytical model that reproduce and explains some of the full Floquet results is derived. The growth-rate σ of the most unstable modes (at small scale, low Reynolds number Re and small wavenumber q) is found to scale differently in the presence or absence of anisotropic kinetic alpha () effect. When an AKA effect is present the scaling σ q\; Re\, predicted by the AKA effect theory [U. Frisch, Z. S. She, and P. L. Sulem, Physica D: Nonlinear Phenomena 28, 382 (1987)] is recovered for Re 1 as expected (with most of the energy of the unstable mode concentrated in the large scales). However, as Re increases, the growth-rate is found to saturate and most of the energy is found at small scales. In the absence of effect, it is found that flows can still have large-scale instabilities, but with a negative eddy-viscosity scaling σ (b Re2-1) q2. The instability appears only above a critical value of the Reynolds number Rec. For values of Re above a second critical value RecS beyond which small-scale instabilities are present, the growth-rate becomes independent of q and the energy of the perturbation at large scales decreases with scale separation. A simple two-modes model is derived that well describes the behaviors of energy concentration and growth-rates of various unstable flows. In the non-linear regime (at moderate values of Re) and in the presence of scale separation, the forcing scale and the largest scales of the system are found to be the most dominant energetically.