Existence and stability of infinite time blow-up in the Keller-Segel system

Abstract

Perhaps the most classical diffusion model for chemotaxis is the Keller-Segel system equation ks0 \ aligned ut =&\; u - ∇ ·(u ∇ v) in R2×(0,∞),\\ v =&\; (-2)-1 u := 12π ∫R2 \, 1|x-z|\,u(z,t)\, dz, \\ & \ u(· ,0) = u0 ≥ 0in R2. aligned . equation We consider the critical mass case ∫R2 u0(x)\, dx = 8π which corresponds to the exact threshold between finite-time blow-up and self-similar diffusion towards zero. We find a radial function u0* with mass 8π such that for any initial condition u0 sufficiently close to u0* the solution u(x,t) of ks0 is globally defined and blows-up in infinite time. As t+∞ it has the approximate profile u(x,t) ≈ 1λ2 U ( x-(t)λ(t) ), U(y)= 8(1+|y|2)2, where λ(t) ≈ c t, \ (t) q for some c>0 and q∈ 2. This result answers affirmatively the nonradial stability conjecture raised in g.