The fast signal diffusion limit in Keller-Segel(-fluid) systems

Abstract

This paper deals with convergence of solutions to a class of parabolic Keller-Segel systems, possibly coupled to the (Navier-)Stokes equations in the framework of the full model eqnarray* \ arraylcl \, \, ∂t nε + uε · ∇ nε &=& nε - ∇ · ( nε S(x, nε, cε)·∇ cε) + f(x, nε, cε), \\[1mm] ε ∂t cε + uε·∇ cε &=& cε - cε + nε , \\[1mm] \,\,∂t uε + (uε·∇) uε &=& uε + ∇ Pε + nε ∇φ, ∇· uε=0 array . eqnarray* to solutions of the parabolic-elliptic counterpart formally obtained on taking ε 0. In smoothly bounded physical domains ⊂ RN with N 1, and under appropriate assumptions on the model ingredients, we shall first derive a general result which asserts certain strong and pointwise convergence properties whenever asserting that supposedly present bounds on ∇ cε and uε are bounded in Lλ((0,T);Lq()) and in L∞((0,T);Lr()), respectively, for some λ∈ (2,∞], q>N and r>\2,N\ such that 1λ+N2q<12. To our best knowledge, this seems to be the first rigorous mathematical result on a fast signal diffusion limit in a chemotaxis-fluid system.