Existence of weak solutions to the two-dimensional incompressible Euler equations in the presence of sources and sinks

TL;DR

This paper proves the existence of weak solutions for the 2D incompressible Euler equations with sources and sinks, using a priori vorticity bounds and compactness methods across various vorticity integrability levels.

Contribution

It establishes the existence of weak solutions for the Euler system with sources and sinks, covering different vorticity integrability cases and employing viscous approximation techniques.

Findings

Existence of solutions for vorticity in L^p with p > 4/3.

Solutions satisfy vorticity equation in distributional, renormalized, or symmetrized sense depending on p.

Method relies on a priori bounds and compactness from viscous approximations.

Abstract

A classical model for sources and sinks in a two-dimensional perfect incompressible fluid occupying a bounded domain dates back to Yudovich in 1966. In this model, on the one hand, the normal component of the fluid velocity is prescribed on the boundary and is nonzero on an open subset of the boundary, corresponding either to sources (where the flow is incoming) or to sinks (where the flow is outgoing). On the other hand the vorticity of the fluid which is entering into the domain from the sources is prescribed. In this paper we investigate the existence of weak solutions to this system by relying on \textit{a priori} bounds of the vorticity, which satisfies a transport equation associated with the fluid velocity vector field. Our results cover the case where the vorticity has a $L^p$ integrability in space, with $p $ in $[1,+\infty]$, and prove the existence of solutions obtained by compactness methods from viscous approximations. More precisely we prove the existence of solutions which satisfy the vorticity equation in the distributional sense in the case where $p >\frac43$, in the renormalized sense in the case where $p >1$, and in a symmetrized sense in the case where $p =1$.