# Global existence and stabilization in a degenerate chemotaxis-Stokes   system with mildly strong diffusion enhancement

**Authors:** Michael Winkler

arXiv: 1704.05648 · 2017-04-20

## TL;DR

This paper proves the global existence and stabilization of solutions in a three-dimensional chemotaxis-Stokes system with mildly strong diffusion, using energy methods and Sobolev regularity, under a specific diffusion condition.

## Contribution

It introduces an analytical approach combining energy arguments and Sobolev regularity to establish global bounded solutions for the chemotaxis-Stokes system with diffusion exponent m>9/8.

## Key findings

- Existence of global bounded weak solutions.
- Solutions approach the homogeneous steady state over time.
- Extended previous results to weaker diffusion conditions.

## Abstract

A class of chemotaxis-Stokes systems generalizing the prototype \[\left\{ \begin{array}{rcl} n_t + u\cdot\nabla n &=& \nabla \cdot \big(n^{m-1}\nabla n\big) - \nabla \cdot \big(n\nabla c\big), c_t + u\cdot\nabla c &=& \Delta c-nc, u_t +\nabla P &=& \Delta u + n \nabla \phi, \qquad \nabla\cdot u =0, \end{array} \right. \] is considered in bounded convex three-dimensional domains, where $\phi\in W^{2,\infty}(\Omega)$ is given. The paper develops an analytical approach which consists in a combination of energy-based arguments and maximal Sobolev regularity theory, and which allows for the construction of global bounded weak solutions to an associated initial-boundary value problem under the assumption that \[ m>\frac{9}{8}. \qquad (\star) \] Moreover, the obtained solutions are shown to approach the spatially homogeneous steady state $(\frac{1}{|\Omega|} \int_\Omega n_0,0,0)$ in the large time limit. This extends previous results which either relied on different and apparently less significant energy-type structures, or on completely alternative approaches, and thereby exclusively achieved comparable results under hypotheses stronger than ($\star$).

## Full text

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## References

44 references — full list in the complete paper: https://tomesphere.com/paper/1704.05648/full.md

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