Emergence of lager densities in chemotaxis system with indirect signal production and non-radial symmetry case

Abstract

This paper deals with the classical solution of the following chemotaxis system with generalized logistic growth and indirect signal production eqnarray \ arrayllll & ut=ε u-∇·(u∇ v)+ru-μ uθ,\\ & 0=d1 v-β v+α w,\\ & 0=d2 w-δ w+γ u array . (0.1)eqnarray and the so-called strong W1, q()-solution of hyperbolic-elliptic-elliptic model eqnarray \ arrayllll & ut=-∇·(u∇ v)+ru-μ uθ,\\ & 0=d1 v-β v+α w,\\ & 0=d2 w-δ w+γ u, array .\ (0.2)eqnarray in arbitrary bounded domain ⊂Rn, n≥1, where r, μ, d1, d2, α, β, γ, δ>0 and θ>1. Via applying the viscosity vanishing method, we first prove that the classical solution of (0.1) will converge to the strong W1, q()-solution of (0.2) as ε→0. After structuring the local well-pose of (0.2), we find that the strong W1, q()-solution will blow up in finite time with non-radial symmetry setting if is a bounded convex domain, θ∈(1, 2], and the initial data is suitable large. Moreover, for any positive constant M and the classical solution of (0.1), if we add another hypothesis that there exists positive constant ε0(M) with ε∈(0,\ ε0(M)), then the classical solution of (0.1) can exceed arbitrarily large finite value in the sense: one can find some points (x, t) such that u(x, t)>M.