Global Existence for a Kinetic Model of Pattern Formation with Density-suppressed Motilities

Abstract

In this paper, we consider global existence of classical solutions to the following kinetic model of pattern formation equation cases ut= (γ (v)u)+μ u(1-u) - v+v=u cases (0.1) equationin a smooth bounded domain ⊂Rn, n≥1 with no-flux boundary conditions. Here, μ≥0 is any given constant. The function γ(·) represents a signal-dependent diffusion motility and is decreasing in v which models a density-suppressed motility in process of stripe pattern formation through self-trapping mechanism [8,20]. The major difficulty in analysis lies in the possible degeneracy of diffusion as v+∞. In the present contribution, based on a subtle observation of the nonlinear structure, we develop a new method to rule out finite-time degeneracy in any spatial dimension for all smooth motility function satisfying γ(v)>0 and γ'(v)≤0 for v≥0. Then we prove global existence of classical solution for (0.1) in the two-dimensional setting with any μ≥0. Moreover, the global solution is proven to be uniform-in-time bounded if either 1/γ satisfies certain polynomial growth condition or μ>0. Besides, we pay particular attention to the specific case γ(v)=e-v with μ=0. A novel critical phenomenon in the two-dimensional setting is observed where blowup takes place in infinite time rather than finite time in our model.