Boundedness and exponential convergence of a chemotaxis model for tumor invasion

Abstract

We revisit the following chemotaxis system modeling tumor invasion equation* cases ut= u-∇ ·(u∇ v),& x∈, t>0,\\ vt= v+wz,& x∈, t>0,\\ wt=-wz,& x∈, t>0,\\ zt= z-z+u, & x∈, t>0,\\ cases equation* in a smooth bounded domain ⊂ Rn(n≥ 1) with homogeneous Neumann boundary and initial conditions. This model was recently proposed by Fujie et al. FIY14 as a model for tumor invasion with the role of extracellular matrix incorporated, and was analyzed by Fujie et al. FIWY16, showing the uniform boundedness and convergence for n≤ 3. In this work, we first show that the L∞-boundedness of the system can be reduced to the boundedness of \|u(·,t)\|Ln4+ε() for some ε>0 alone, and then, for n≥ 4, if the initial data \|u0\|Ln4, \|z0\|Ln2 and \|∇ v0 \|Ln are sufficiently small, we are able to establish the L∞-boundedness of the system. Furthermore, we show that boundedness implies exponential convergence with explicit convergence rate, which resolves the open problem left in FIWY16.