Incompressible flow around a small obstacle and the vanishing viscosity limit

TL;DR

This paper investigates the conditions under which viscous flow around a small obstacle converges to an ideal flow as both viscosity and obstacle size vanish, extending understanding of the vanishing obstacle limit in fluid dynamics.

Contribution

It establishes convergence criteria for Navier-Stokes solutions to Euler solutions in the vanishing viscosity and obstacle size limit, assuming initial velocity convergence and obstacle smallness.

Findings

Convergence occurs if initial velocities converge strongly in L^2.

Obstacle diameter must be smaller than a constant times viscosity.

Results depend on the smoothness and existence of the limit solution.

Abstract

In this article we consider viscous flow in the exterior of an obstacle satisfying the standard no-slip boundary condition at the surface of the obstacle. We seek conditions under which solutions of the Navier-Stokes system in the exterior domain converge to solutions of the Euler system in the full space when both viscosity and the size of the obstacle vanish. We prove that this convergence is true assuming two hypothesis: first, that the initial exterior domain velocity converges strongly in $L^2$ to the full-space initial velocity and second, that the diameter of the obstacle is smaller than a suitable constant times viscosity, or, in other words, that the obstacle is sufficiently small. The convergence holds as long as the solution to the limit problem is known to exist and stays sufficiently smooth. This work complements the study of incompressible flow around small obstacles, which has been carried out in [1,2,3] [1] D. Iftimie and J. Kelliher, {\it Remarks on the vanishing obstacle limit for a 3D viscous incompressible fluid.} Preprint available at http://math.univ-lyon1.fr/~iftimie/ARTICLES/viscoushrink3d.pdf . [2] D. Iftimie, M. C. Lopes Filho, and H. J. Nussenzveig Lopes. {\it Two dimensional incompressible ideal flow around a small obstacle.} Comm. Partial Differential Equations {\bf 28} (2003), no. 1-2, 349--379. [3] D. Iftimie, M. C. Lopes Filho, and H. J. Nussenzveig Lopes. {\it Two dimensional incompressible viscous flow around a small obstacle.} Math. Ann. {\bf 336} (2006), no. 2, 449--489.