# Finite-time blow-up in a two-dimensional Keller--Segel system with an   environmental dependent logistic source

**Authors:** Mario Fuest

arXiv: 1905.04513 · 2019-09-12

## TL;DR

This paper investigates finite-time blow-up and global existence in a 2D Keller--Segel chemotaxis system with environmental-dependent logistic source, revealing critical mass phenomena and conditions for blow-up or global solutions.

## Contribution

It establishes conditions under which solutions blow up or exist globally, highlighting the role of environmental factors and nonlinearities in the Keller--Segel system.

## Key findings

- Solutions blow up in finite time for initial mass above 8π.
- Solutions are global for initial mass below 8π when κ ≡ 0.
- Global solutions exist for p > 2 with certain growth conditions on μ.

## Abstract

The Neumann initial-boundary problem for the chemotaxis system \begin{align} \label{prob:abstract} \tag{$\star$}   \begin{cases}   u_t = \Delta u - \nabla \cdot (u \nabla v) + \kappa(|x|) u - \mu(|x|) u^p, \\   0 = \Delta v - \frac{m(t)}{|\Omega|} + u, \quad m(t) := \int_\Omega u(\cdot, t)   \end{cases} \end{align} is studied in a ball $\Omega = B_R(0) \subset \mathbb R^2$, $R \gt 0$ for $p \ge 1$ and sufficiently smooth functions $\kappa, \mu: [0, R] \rightarrow [0, \infty)$.   We prove that whenever $\mu', -\kappa' \ge 0$ as well as $\mu(s) \le \mu_1 s^{2p-2}$ for all $s \in [0, R]$ and some $\mu_1 \gt 0$ then for all $m_0 \gt 8 \pi$ there exists $u_0 \in C^0(\overline \Omega)$ with $\int_\Omega u_0 = m_0$ and a solution $(u, v)$ to \eqref{prob:abstract} with initial datum $u_0$ blowing up in finite time. If in addition $\kappa \equiv 0$ then all solutions with initial mass smaller than $8 \pi$ are global in time, displaying a certain critical mass phenomenon.   On the other hand, if $p \gt 2$, we show that for all $\mu$ satisfying $\mu(s) \ge \mu_1 s^{p-2-\varepsilon}$ for all $s \in [0, R]$ and some $\mu_1, \varepsilon \gt 0$ the system \eqref{prob:abstract} admits a global classical solution for each initial datum $0 \le u_0 \in C^0(\overline \Omega)$

## Full text

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## References

38 references — full list in the complete paper: https://tomesphere.com/paper/1905.04513/full.md

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Source: https://tomesphere.com/paper/1905.04513