Diffusion-free boundary conditions for the Navier-Stokes equations

Abstract

We provide a mathematical analysis of the `diffusion-free' boundary conditions recently introduced by Lin and Kerswell for the numerical treatment of inertial waves in a fluid contained in a rotating sphere. We consider here the full setting of the nonlinear Navier-Stokes equation in a general bounded domain of Rd, d=2 or 3. We show that diffusion-free boundary conditions u · τ ∂ = 0, u · n∂ = 0 when d=2, u × n∂ = 0, u · n∂ = 0 when d=3, allow for a satisfactory well-posedness theory of the full Navier-Stokes equations (global in time for d=2, local for d=3). Moreover, we perform a boundary layer analysis in the limit of vanishing viscosity → 0. We establish that the amplitude of the boundary layer flow is in this case of order , i.e. much lower than in the case of standard Dirichlet or even stress-free conditions. This confirms analytically that this choice of boundary conditions may be used to reduce diffusive effects in numerical studies relying on the Navier-Stokes equation to approach nearly inviscid solutions.