Blow-up prevention by nonlinear diffusion in a 2D Keller-Segel-Navier-Stokes system with rotational flux

Abstract

This paper investigates the following Keller-Segel-Navier-Stokes system with nonlinear diffusion and rotational flux aligncases &nt+u·∇ n= nm-∇·(nS(x, n, c)∇ c), &x∈ , t>0, \\ &ct+u·∇ c= c-c+n, &x∈ , t>0, \\ &ut+ (u·∇)u+∇ P= u+n∇ φ, &x∈ , t>0, \\ &∇· u=0, &x∈ , t>0, casesalign where ∈ R,φ∈ W2,∞() and S is a given function with values in R2×2 which fulfills |S(x,n,c)| ≤ CS with some C S > 0. Systems of this type describe chemotaxis-fluid interaction in cases when the evolution of the chemoattractant is essentially dominated by production through cells. If m>1 and ⊂ R2 is a bounded domain with smooth boundary, then for all reasonably regular initial data, a corresponding initial-boundary value problem for (KSNF) possesses a global and bounded (weak) solution, which significantly improves previous results of several authors. Moreover, the optimal condition on the parameter m for global existence is obtained. Our approach underlying the derivation of main result is based on an entropy-like estimate involving the functional %Our main tool is consideration of the energy functional ∫(n +)m+∫|∇ c|2, where n and c are components of the solutions to (2.1) below.