Dynamics in chemotaxis models of parabolic-elliptic type on bounded domain with time and space dependent logistic sources

Abstract

This paper considers the dynamics of the following chemotaxis system cases ut= u-∇ (u· ∇ v)+u(a0(t,x)-a1(t,x)u-a2(t,x)∫u), x∈ 0= v+ u-v, x∈ ∂ u∂ n=∂ v∂ n=0, x∈∂, cases where ⊂ Rn(n≥ 1) is a bounded domain with smooth boundary ∂ and ai(t,x) (i=0,1,2) are locally H\"older continuous in t∈R uniformly with respect to x∈ and continuous in x∈. We first prove the local existence and uniqueness of classical solutions (u(x,t;t0,u0),v(x,t;t0,u0)) with u(x,t0;t0,u0)=u0(x) for various initial functions u0(x). Next, under some conditions on the coefficients a1(t,x), a2(t,x), and n, we prove the global existence and boundedness of classical solutions (u(x,t;t0,u0),v(x,t;t0,u0)) with given nonnegative initial function u(x,t0;t0,u0)=u0(x). Then, under the same conditions for the global existence, we show that the system has an entire positive classical solution (u*(x,t),v*(x,t)). Moreover, if ai(t,x) (i=0,1,2) are periodic in t with period T or are independent of t, then the system has a time periodic positive solution (u*(x,t),v*(x,t)) with periodic T or a steady state positive solution (u*(x),v*(x)). If ai(t,x) (i=0,1,2) are independent of x , then the system has a spatially homogeneous entire positive solution (u*(t),v*(t)). Finally, under some further assumptions, we prove that the system has a unique entire positive solution (u*(x,t),v*(x,t)) which is globally stable . Moreover, if ai(t,x) (i=0,1,2) are periodic or almost periodic in t, then (u*(x,t),v*(x,t)) is also periodic or almost periodic in t.