How far do chemotaxis-driven forces influence regularity in the Navier-Stokes system?

Abstract

© 2016 American Mathematical Society. The chemotaxis-Navier-Stokes system [Formula Presented] is considered under boundary conditions of homogeneous Neumann type for n and c, and Dirichlet type for u, in a bounded convex domain Ω ⊂ R3with smooth boundary, where Φ ∈ W1,∞(Ω) and χ and f are sufficiently smooth given functions generalizing the prototypes χ ≢ const. and f(s) = s for s ≥ 0. It is known that for all suitably regular initial data n0, c0 and u0 satisfying 0 ≢ n0≥ 0, c0≥ 0 and ∇·u0= 0, a corresponding initial-boundary value problem admits at least one global weak solution which can be obtained as the pointwise limit of a sequence of solutions to appropriately regularized problems. The present paper shows that after some relaxation time, this solution enjoys further regularity properties and thereby complies with the concept of eventual energy solutions, which is newly introduced here and which inter alia requires that two quasi-dissipative inequalities are ultimately satisfied. Moreover, it is shown that actually for any such eventual energy solution (n, c, u) there exists a waiting time T0∈ (0, ∞) with the property that (n, c, u) is smooth in Ω × [T0, ∞) and that [Formula Presented] c(x, t) →0 and u(x, t) → 0 hold as t → ∞, uniformly with respect to x ∈Ω. This resembles a classical result on the three-dimensional Navier-Stokes system, asserting eventual smoothness of arbitrary weak solutions thereof which additionally fulfill the associated natural energy inequality. In consequence, our results inter alia indicate that under the considered boundary conditions, the possibly destabilizing action of chemotactic cross-diffusion in (⋆) does not substantially affect the regularity properties of the fluid flow at least on large time scales.