Classification of self-similar singular solutions with large mass for Keller-Segel model with signal consumption

Abstract

In this paper, we concentrate on investigating the self-similar singular solutions of Keller-Segel model with signal consumption (-uvα) and singular sensitivity. We perform a detailed exploration into the existence and decay rate of self-similar solutions, particularly, the permissibility of arbitrary mass for these solutions across all possible cases. Based on these findings, we can delve deeper into verifying that these self-similar solutions (u, v) exhibit varying degrees of singularity depending on the value of α and the spatial dimension. Our analysis reveals that the component u (with arbitrary mass) of the solution consistently behaves analogous to heat kernel, that is, u exhibiting a Dirac δ initial singularity identical to that of the fundamental solution, and converges to 0 in the sense of the Lp-norm (p>1) as time approaches infinity. However, the initial behavior of the other component v varies significantly based on the value of α and the spatial dimension, exhibiting regularity (not singular), less singularity, or strong singularity (more singular than fundamental solution). Moreover, both u and v undergo instantaneous smoothing, becoming smooth immediately after t>0. This phenomenon reveals the adaptive strategies of cells in high-density aggregation environments to prevent resource depletion, reflecting an optimization process of self-organizing behavior.

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