A degenerate chemotaxis system with flux limitation: Maximally extended solutions and absence of gradient blow-up

Abstract

This paper aims at providing a first step toward a qualitative theory for a new class of chemotaxis models derived from the celebrated Keller-Segel system, with the main novelty being that diffusion is nonlinear with flux delimiter features. More precisely, as a prototypical representative of this class we study radially symmetric solutions of the parabolic-elliptic system (see the text). Under the initial condition u|t=0=u0>0 and no-flux boundary conditions in balls ⊂Rn, where >0 and μ:=1|| ∫ u0. The main results assert the existence of a unique classical solution, extensible in time up to a maximal Tmax ∈ (0,∞] which has the property that if Tmax<∞ then t Tmax \|u(·,t)\|L∞()=∞. () The proof therefore is mainly based on comparison methods, which firstly relate pointwise lower and upper bounds for the spatial gradient ur to L∞ bounds for u and to upper bounds for z:=utu; secondly, another comparison argument involving nonlocal nonlinearities provides an appropriate control of z+ in terms of bounds for u and |ur|, with suitably mild dependence on the latter. As a consequence of () by means of suitable a priori estimates it is moreover shown that the above solutions are global and bounded when either n 2 \ and <1, or n=1, \ >0 \ and m<mc, with mc:=12-1 if >1 and mc:=∞ if 1. That these conditions are essentially optimal will be shown in a forthcoming paper in which () will be used to derive complementary results on the occurrence of solutions blowing up in finite time with respect to the norm of u in L∞().