Self-similar Dynamics in the Critical p-Laplacian Patlak-Keller-Segel Model: Shrinking Blow-up and Expanding Propagation

Abstract

In this paper, we study the following Patlak-Keller-Segel model with p-Laplacian diffusion align* \ aligned & t=∇ · ( | ∇ |p-2∇ ) - ∇ · ( ∇ c ), &0= c+ m, aligned. align* and the exponent m>0 is chosen as m = (p-2)N + pN. This relation ensures the scale invariance of the system and is conjectured to be the critical exponent that separates global boundedness from finite-time blow-up. We prove that, at the critical threshold m=(p-2)N + pN, the system indeed admits finite-time blow-up solutions. More precisely, in the slow diffusion regime p>2, there exist backward self-similar blow-up solutions that are radially decreasing, compactly supported, and concentrate into a Dirac δ-measure at the blow-up time T; and their supports shrink toward the origin at the rate (T-t)1mN. For the fast diffusion case 1<p 2, we show that there are no backward self-similar blow-up solutions with finite-mass. Additionally, we also explore forward self-similar solutions in both the slow diffusion and fast diffusion cases. These solutions also carry finite mass and exhibit a Dirac δ-singularity at the initial moment. Specifically, in the slow diffusion case, the support expands at the rate t1mN, whereas in the fast diffusion case, the solution becomes strictly positive for all positive times. Our work provides the first blow up analysis for the p-Laplacian Keller-Segel system when p 2, and it confirms that the exponent m given above is indeed the sharp threshold between global existence and finite time singularity formation.

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