On the global stability and large time behavior of solutions of the Boussinesq equations

Abstract

We study the two dimensional viscous Boussinesq equations, which model stratified flows in a circular domain under the influence of a general gravitational potential f. First, we show that the Boussinesq equations admit steady-state solutions only in the form of hydrostatic equilibria, (u,,p) = (0, s, ps), where the pressure gradient satisfies ∇ ps = -s ∇ f. Moreover, the relation between s and f is constrained by (∂y s, -∂x s) · (∂x f, ∂y f) = 0, which allows us to write ∇ s = h(x,y) ∇ f for some scalar function h(x,y). Second, we prove that any hydrostatic equilibrium (0, s, ps) is linearly unstable if h(x0, y0) > 0 at some point (x, y) = (x0, y0). This instability coincides with the classical Rayleigh--Taylor instability. Third, by employing a series of regularity estimates, we reveal that although the presence of the Rayleigh--Taylor instability makes perturbations around the unstable equilibrium grow exponentially in time, the system ultimately converges to a state of hydrostatic equilibrium. The analysis is carried out for perturbations about an arbitrary hydrostatic equilibrium, covering both stable and unstable configurations. Finally, we derive a necessary and sufficient condition on the initial density perturbation under which the density converges to a profile of the form -γ f + β with constants γ, β > 0. This result underscores the system's inherent tendency to settle into a hydrostatic state, even in the presence of Rayleigh--Taylor instability.

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