Boundedness and finite-time blow-up in a repulsion-consumption system with nonlinear chemotactic sensitivity

Abstract

This paper investigates the repulsion-consumption system align \ arrayll ut= u+∇ ·(S(u) ∇ v), τ vt= v-u v, array . align under no-flux/Dirichlet conditions for u and v in a ball BR(0) ⊂ Rn . When τ=\0,1\ and 0<S(u)≤slant K(1+u)β for u ≥slant 0 with some β ∈ (0,n+22n) and K>0, we show that for any given radially symmetric initial data, the problem () possesses a global bounded classical solution. Conversely, when τ=0, n=2 and S(u) ≥slant k uβ for u ≥slant 0 with some β>1 and k>0, for any given initial data u0, there exists a constant M=M(u0)>0 with the property that whenever the boundary signal level M≥slant M, the corresponding radially symmetric solution blows up in finite time. Our results can be compared with that of the papers [J.~Ahn and M.~Winkler, Calc. Var. 64 (2023).] and [Y. Wang and M. Winkler, Proc. Roy. Soc. Edinburgh Sect. A, 153 (2023).], in which the authors studied the system () with the first equation replaced respectively by ut=∇ · ((1+u)-α ∇ u)+∇ ·(u ∇ v) and ut=∇ · ((1+u)-α ∇ u)+∇ ·(uv ∇ v). Among other things, they obtained that, under some conditions on u0(x) and the boundary signal level, there exists a classical solution blowing up in finite time whenever α>0.