Yudovich theory under geometric regularity for density-dependent incompressible fluids

Abstract

This paper focuses on the study of the density-dependent incompressible Euler equations in space dimension d=2, for low regularity (i.e. non-Lipschitz) initial data satisfying assumptions in spirit of the celebrated Yudovich theory for the classical homogeneous Euler equations. We show that, under an a priori control of a non-linear geometric quantity, namely the directional derivative ∂Xu of the fluid velocity u along the vector field X:=∇, where is the fluid density, low regularity solutions \`a la Yudovich can be constructed also in the non-homogeneous setting. More precisely, we prove the following facts: (i) stability: given a sequence of smooth approximate solutions enjoying a uniform control on the above mentioned geometric quantity, then (up to an extraction) that sequence converges to a Yudovich-type solution of the density-dependent incompressible Euler system; \\ (ii) uniqueness: there exists at most one Yudovich-type solution of the density-dependent incompressible Euler equations such that ∂Xu remains finite; besides, this statement improves previous uniqueness results for regular solutions, inasmuch as it requires less smoothness on the initial data.