Nonlinear stability results for plane Couette and Poiseuille flows

Abstract

In this article we prove, choosing an appropriately weighted L2-energy equivalent to the classical energy, that the plane Couette and Poiseuille flows are nonlinearly stable with respect to streamwise perturbations for any Reynolds number. In this case the coefficient of time-decay of the energy is π2/(2 Re), and it is a bound from above of the time-decay of streamwise perturbations of linearized equations. We also prove that the plane Couette and Poiseuille flows are nonlinearly stable if the Reynolds number is less then ReOrr/ when the perturbation is a tilted perturbation, i.e. 2D perturbations with wave vector which forms an angle ∈ [0, π/2] with the direction i of the motion. ReOrr is the Orr (1907) critical Reynolds number for spanwise perturbations which, for the Couette flow is ReOrr=177.22 and for the Poiseuille flow is ReOrr=175.31. In particular these results improve those obtained by Joseph (1966), who found for streamwise perturbations a critical nonlinear value of 82.6 in the Couette case, and those obtained by Joseph and Carmi (1969), who found the value 99.1 for plane Poiseuille flow for streamwise perturbations. The results we obtain here are, for any angle, in a good agreement with the experiments (see Prigent et al. 2003) and the numerical simulations (see Barckley and Tuckerman 2005, 2007).