Sharp macroscopic blow-up behavior for the parabolic-elliptic Keller-Segel system in dimensions n 3

Abstract

We study the space-time concentration or blow-up asymptotics of radially decreasing solutions of the parabolic-elliptic Keller-Segel system in the whole space or in a ball. We show that, for any solution in dimensions 3 n 9 (assuming finite mass in the whole space case), there exists a nonflat backward self-similar solution U such that u(x,t)=(1+o(1))U(x,t),as (x,t) (0,T). This macroscopic behavior is important from the physical point of view, since it gives a sharp description of the concentration phenomenon in the scale of the original space-time variables~(x,t). It strongly improves on existing results, since such behavior was previously known (GMS) to hold only in the microscopic scale |x| O(T-t) as t T (and in the whole space case only). As a consequence, we obtain the two-sided global estimate C1 (T-t+|x|2)u(x,t) C2in BR×(T/2,T), whose upper part only was known before (Soup-Win), as well as the sharp final profile: x 0 |x|2u(x,T)=L∈(0,∞). The latter improves, with a different proof, the recent result of BZ by excluding the possibility L=0. We also give extensions of these results, in higher dimensions, to type~I and to time monotone solutions. Moreover, we extend the known results on type I estimates and on convergence in similarity variables, and significantly simplify their proofs.