Stability Results for Idealised Shear Flows on a Rectangular Periodic Domain

Abstract

We present a new linearly stable solution of the Euler fluid flow on a torus. On a two-dimensional rectangular periodic domain [0,2π)×[0,2π / ) for ∈R+, the Euler equations admit a family of stationary solutions given by the vorticity profiles *(x)= (p1x1+ p2x2). We show linear stability for such flows when p2=0 and ≥ |p1| (equivalently p1=0 and |p2|≤1). The classical result due to Arnold is that for p1 = 1, p2 = 0 and 1 the stationary flow is nonlinearly stable via the energy-Casimir method. We show that for |p1| 2, p2 = 0 the flow is linearly stable, but one cannot expect a similar nonlinear stability result. Finally we prove nonlinear instability for all equilibria satisfying p12+2p22>3(2+1)4(7-43). The modification and application of a structure-preserving Hamiltonian truncation is discussed for the ≠ 1 case. This leads to an explicit Lie-Poisson integrator for the truncated system.