Bounds on solutions of the rotating, stratified, incompressible, non-hydrostatic, three-dimensional Boussinesq equations

Abstract

We study the three-dimensional, incompressible, non-hydrostatic Boussinesq fluid equations, which are applicable to the dynamics of the oceans and atmosphere. These equations describe the interplay between velocity and buoyancy in a rotating frame. A hierarchy of dynamical variables is introduced whose members m(t) (1 ≤ m < ∞) are made up from the respective sum of the L2m-norms of vorticity and the density gradient. Each m(t) has a lower bound in terms of the inverse Rossby number, Ro-1, that turns out to be crucial to the argument. For convenience, the m are also scaled into a new set of variables Dm(t). By assuming the existence and uniqueness of solutions, conditional upper bounds are found on the Dm(t) in terms of Ro-1 and the Reynolds number Re. These upper bounds vary across bands in the \D1,\,Dm\ phase plane. The boundaries of these bands depend subtly upon Ro-1, Re, and the inverse Froude number Fr-1. For example, solutions in the lower band conditionally live in an absorbing ball in which the maximum value of 1 deviates from Re3/4 as a function of Ro-1,\,Re and Fr-1.