Can a chemotaxis-consumption system recover from a measure-type aggregation state in arbitrary dimension? (2308.14934v1)

Abstract: We consider the chemotaxis-consumption system [ \left{ \begin{aligned} u_t &= \Delta u - \chi \nabla \cdot (u\nabla v) \ v_t &= \Delta v - uv \end{aligned} \right. ] in a smooth bounded domain $\Omega \subseteq \mathbb{R}^n$, $n \geq 2$, with parameter $\chi > 0$ and Neumann boundary conditions. It is well known that, for sufficiently smooth nonnegative initial data and under a smallness condition for the initial state of $v$, solutions of the above system never blow up and are even globally bounded. Going in a sense a step further in this paper, we ask the question whether the system can even recover from an initial state that already resembles measure-type blowup. To answer this, we show that, given an arbitrarily large positive Radon measure $u_0$ with $u_0(\overline{\Omega}) > 0$ as the initial data for the first equation and a nonnegative $L^\infty(\Omega)$ function $v_0$ with [ 0 < |v_0|_{L^{\infty}(\Omega)} < \frac{2}{3n\chi} ] as initial data for the second equation, it is still possible to construct a global classic solution to the above system.