Convergence of boundary layers of chemotaxis models with physical boundary conditions~II: Non-degenerate
Abstract
This paper establishes the convergence of boundary-layer solutions of the consumption type Keller-Segel model with non-degenerate initial data subject to physical boundary conditions, which is a sequel of Corrillo-Hong-Wang-vanishing on the case of degenerate initial data. Specifically, we justify that the solution with positive chemical diffusion rate >0 converges to the solution with zero diffusion =0 (outer-layer solution) plus the boundary-layer profiles (inner-layer solution) for any time t>0 as → 0 . Compared to Corrillo-Hong-Wang-vanishing, the main difficulty in the analysis is the lack of regularity of the outer- and boundary-layer profiles since only the zero-order compatibility conditions for the leading-order boundary-layer profiles can be fulfilled with non-degenerate initial data. Our new strategy is to regularize the boundary-layer profiles with carefully designed corner-corrector functions and approximate the low-regularity leading-order boundary-layer profiles by higher-regularity profiles with regularized boundary conditions. By using delicate weight functions involving boundary-layer profiles to cancel the multi-scaled linear terms in the perturbed equations, we manage to obtain the requisite uniform-in- estimates for the convergence analysis. This cancellation technique enables us to prove the convergence to boundary-layer solutions for any time t >0 , which is different from the convergence result in Corrillo-Hong-Wang-vanishing which holds true only for some finite time depending on the Dirichlet boundary value.
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