Critical mass phenomena in higher dimensional quasilinear Keller-Segel systems with indirect signal production

Abstract

In this paper, we deal with quasilinear Keller--Segel systems with indirect signal production, cases ut = ∇ · ((u+1)m-1∇ u) - ∇ · (u ∇ v), &x ∈ ,\ t> 0,\\ 0 = v - μ(t) + w, &x ∈ ,\ t> 0,\\ wt + w = u, &x ∈ ,\ t> 0, cases complemented with homogeneous Neumann boundary conditions and suitable initial conditions, where ⊂ Rn (n3) is a bounded smooth domain, m1 and μ(t) := 1|| w(·, t) for\ t>0. We show that in the case m2-2n, there exists Mc>0 such that if either m>2-2n or ∫ u0 <Mc, then the solution exists globally and remains bounded, and that in the case m2-2n, if either m<2-2n or M>2n2nn-1ωn, then there exist radially symmetric initial data such that ∫ u0 = M and the solution blows up in finite or infinite time, where the blow-up time is infinite if m=2-2n. In particular, if m=2-2n there is a critical mass phenomenon in the sense that ∈f\M > 0 : ∃ u0 with ∫ u0 = M such that the corresponding solution blows up in infinite time\ is a finite positive number.