Global existence for non-homogeneous incompressible inviscid fluids in presence of Ekman pumping

Abstract

In this paper, we study the global solvability of the density-dependent incompressible Euler equations, supplemented with a damping term of the form Dαγ(, u) = α γ u , where α>0 and γ ∈ \0,1\ . To some extent, this system can be seen as a simplified model describing the mean dynamics in the ocean; from this perspective, the damping term can be interpreted as a term encoding the effects of the celebrated Ekman pumping in the system. On the one hand, in the general case of space dimension d≥ 2, we establish global well-posedness in the Besov spaces framework, under a non-linear smallness condition involving the size of the initial velocity field u0, of the initial non-homogeneity 0-1 and of the damping coefficient α. On the other hand, in the specific situation of planar motions and damping term with γ=1, we exhibit a second smallness condition implying global existence, which in particular yields global well-posedness for arbitrarily large initial velocity fields, provided the initial density variations 0-1 are small enough. The formulated smallness conditions rely only on the endpoint Besov norm B1∞,1 of the initial datum, whereas, as a byproduct of our analysis, we derive exponential decay of the velocity field and of the pressure gradient in the high regularity norms Bsp,r.