Refined description and stability for singular solutions of the 2D Keller-Segel system

Abstract

We construct solutions to the two dimensional parabolic-elliptic Keller-Segel model for chemotaxis that blow up in finite time T. The solution is decomposed as the sum of a stationary state concentrated at scale λ and of a perturbation. We rely on a detailed spectral analysis for the linearized dynamics in the parabolic neighbourhood of the singularity performed by the authors, providing a refined expansion of the perturbation. Our main result is the construction of a stable dynamics in the full nonradial setting for which the stationary state collapses with the universal law λ 2e-2+γ2T-te-| (T-t)|2 where γ is the Euler constant. This improves on the earlier result by Raphael and Schweyer 2014 and gives a new robust approach to so-called type II singularities for critical parabolic problems. A by-product of the spectral analysis we developed is the existence of unstable blowup dynamics with speed λ C0(T-t)2 |(T-t)|-2( - 1) for ≥ 2 integer.