Critical mass for infinite-time aggregation in a chemotaxis model with indirect signal production

Abstract

We study the Neumann initial-boundary problem for the chemotaxis system \arrayll ut= u - ∇ · (u∇ v), & x∈ , \, t>0, 0= v - μ(t)+w, & x∈ , \, t>0, τ wt + δ w = u, & x∈ , \, t>0, array . () in the unit disk :=B1(0)⊂ 2, where δ 0 and τ>0 are given parameters and μ(t):= w(x,t)dx, t>0. It is shown that this problem exhibits a novel type of critical mass phenomenon with regard to the formation of singularities, which drastically differs from the well-known threshold property of the classical Keller-Segel system, as obtained upon formally taking τ 0, in that it refers to blow-up in infinite time rather than in finite time: Specifically, it is first proved that for any sufficiently regular nonnegative initial data u0 and w0, () possesses a unique global classical solution. In particular, this shows that in sharp contrast to classical Keller-Segel-type systems reflecting immediate signal secretion by the cells themselves, the indirect mechanism of signal production in () entirely rules out any occurrence of blow-up in finite time. However, within the framework of radially symmetric solutions it is next proved that whenever δ>0 and u0<8πδ, the solution remains uniformly bounded, whereas for any choice of δ 0 and m>8πδ, one can find initial data such that u0=m, and such that for the corresponding solution we have \|u(·,t)\|L∞() ∞ as t∞.