This paper aims at providing an alternative approach to study global dynamic properties for a two-species chemotaxis model, with the main novelty being that both populations mutually compete with the other on account of the Lotka-Volterra dynamics. More precisely, we consider the following Neumann initial-boundary value problem {u(t) = d(1)Delta u - chi(1)del center dot (u del w) + mu(1)u(1 - u - a(1)v), x epsilon Omega, t > 0, v(t) = d(2)Delta v - chi(2)del center dot (v del w) + mu(2)v(1 - a(2)u - v), x epsilon Omega t > 0 , 0 = d(3 Delta)w - w + u + v, x epsilon Omega, t > 0, in a bounded domain Omega subset of R-n, n >= 1, with smooth boundary, where d(1), d(2), d(3), chi(1), chi(2), mu(1), mu(2), a(1), a(2) are positive constants. When a(1) epsilon (0, 1) and a(2) epsilon (0, 1), it shown that under some explicit largeness assumptions on the logistic growth coefficients mu(1) and mu(2), the corresponding Neumann initial boundary value problem possesses a unique global bounded solution which moreover approaches a unique positive homogeneous steady state (u*, v*, w*) of above system in the large time limit. The respective decay rate of this convergence is shown to be exponential. When a(1) >= 1 and a(2) epsilon (0, 1), if mu(2) is suitable large, for all sufficiently regular nonnegative initial data u(0) and v(0) with u(0) not equivalent to 0 and v(0) not equivalent to 0, the globally bounded solution of above system will stabilize toward (0, 1, 1) as t -> infinity in algebraic.

• 出版日期2018-2-1
• 单位重庆大学; 西南财经大学