Finite-time blow-up in fully parabolic quasilinear Keller-Segel systems with supercritical exponents

Abstract

We examine the possibility of finite-time blow-up of solutions to the fully parabolic quasilinear Keller--Segel model alignprob:star cases ut = ∇ · ((u+1)m-1∇ u - u(u+1)q-1∇ v) & in × (0, T), \\ vt = v - v + u & in × (0, T) cases align in a ball ⊂ Rn with n≥ 2. Previous results show that unbounded solutions exist for all m, q ∈ R with m-q<n-2n, which, however, are necessarily global in time if q ≤ 0. It is expected that finite-time blow-up is possible whenever q > 0 but in the fully parabolic setting this has so far only been shown when \m, q\ ≥ 1. In the present paper, we substantially extend these findings. Our main results for the two- and three-dimensional settings state that prob:star admits solutions blowing up in finite time if align* m-q<n-2n and cases q < 2m & if n = 2, \\ q < 2m - 23 or m > 23 & if n = 3, cases align* that is, also for certain m, q with \m, q\ < 1. As a key new ingredient in our proof, we make use of (singular) pointwise upper estimates for u.