The Hydrostatic Stokes Semigroup and Well-Posedness of the Primitive Equations on Spaces of Bounded Functions

Abstract

Consider the 3-d primitive equations in a layer domain =G × (-h,0), G=(0,1)2, subject to mixed Dirichlet and Neumann boundary conditions at z=-h and z=0, respectively, and the periodic lateral boundary condition. It is shown that this equation is globally, strongly well-posed for arbitrary large data of the form a=a1 + a2, where a1∈ C(G;Lp(-h,0)), a2∈ L∞(G;Lp(-h,0)) for p>3, and where a1 is periodic in the horizontal variables and a2 is sufficiently small. In particular, no differentiability condition on the data is assumed. The approach relies on L∞HLpz()-estimates for terms of the form t1/2 ∂z etAσPf L∞H Lpz() C etβ f L∞H Lpz () for t>0, where et Aσ denotes the hydrostatic Stokes semigroup. The difficulty in proving estimates of this form is that the hydrostatic Helmholtz projection P fails to be bounded with respect to the L∞-norm. The global strong well-posedness result is then obtained by an iteration scheme, splitting the data into a smooth and a rough part and by combining a reference solution for smooth data with an evolution equation for the rough part.