Global solutions in the species competitive chemotaxis system with inequal diffusion rates (Q2398550)

Summary: This paper is devoted to studying the two-species competitive chemotaxis system with signal-dependent chemotactic sensitivities and inequal diffusion rates \(u_{1 t} = \Delta u_1 - \nabla \cdot \left(u_1 \chi_1 \left(v\right) \nabla v\right) + \mu_1 u_1 \left(1 - u_1 - a_1 u_2\right)\), \(x \in \Omega\), \(t > 0\), \(u_{2 t} = \Delta u_2 - \nabla \cdot \left(u_2 \chi_2 \left(v\right) \nabla v\right) + \mu_2 u_2 \left(1 - a_2 u_1 - u_2\right)\), \(x \in \Omega\), \(t > 0\), \(v_t = \tau \Delta v - \gamma v + u_1 + u_2\), \(x \in \Omega\), \(t > 0\), under homogeneous Neumann boundary conditions in a bounded and regular domain \(\Omega \subset \mathbb{R}^n\) (\(n \geq 1\)). If the nonnegative initial date \((u_{10}, u_{20}, v_0) \in(C^1(\overline{\Omega}))^3\) and \(v_0 \in(\underline{v}, \overline{v})\) where the constants \(\overline{v} > \underline{v} \geq 0\), the system possesses a unique global solution that is uniformly bounded under some suitable assumptions on the chemotaxis sensitivity functions \(\chi_1(v)\), \(\chi_2(v)\) and linear chemical production function \(- \gamma v + u_1 + u_2\).