Asymptotic behavior of 2D incompressible ideal flow around small disks

Abstract

In this article, we study the homogenization limit of a family of solutions to the incompressible 2D Euler equations in the exterior of a family of nk disjoint disks with centers \zki\ and radii k. We assume that the initial velocities u0k are smooth, divergence-free, tangent to the boundary and that they vanish at infinity. We allow, but we do not require, nk ∞, and we assume k 0 as k ∞. Let γki be the circulation of u0k around the circle \|x-zki|=k\. We prove that the homogenization limit retains information on the circulations as a time-independent coefficient. More precisely, we assume that: (1) ω0k = curl u0k has a uniform compact support and converges weakly in Lp0, for some p0>2, to ω0 ∈ Lp0c(R2), (2) Σi=1nk γki δzki μ weak- in BM(R2) for some bounded Radon measure μ, and (3) the radii k are sufficiently small. Then the corresponding solutions uk converge strongly to a weak solution u of a modified Euler system in the full plane. This modified Euler system is given, in vorticity formulation, by an active scalar transport equation for the quantity ω= curl u, with initial data ω0, where the transporting velocity field is generated from ω so that its curl is ω + μ. As a byproduct, we obtain a new existence result for this modified Euler system.