Exponential speed of uniform convergence of the cell density toward equilibrium for subcritical mass in a Patlak-Keller-Segel model

Abstract

This paper is concerned with a chemotaxis aggregation model for cells, more precisely with a parabolic-elliptic semilinear Patlak-Keller-Segel system in a ball of RN for N≥ 2. For N=2, this system is well known for its critical mass 8π. It has been proved in Montaru2 that it also exhibits a critical mass phenomenon for N≥ 3. The main result of this paper is the exponential speed of uniform convergence of radial solutions toward the unique steady state in the subcritical case for N≥ 2. We stress that this covers in particular the classical Keller-Segel system with N=2, and that the result improves on the known results even for this most studied problem. A key tool is an associated one-dimensional degenerate parabolic problem (PDEm) where m is proportional to the total mass of cells. The proof exploits its formal gradient flow structure ut=-∇ F[u(t)] on an "infinite dimensional Riemannian manifold". In particular, we show a new Hardy type inequality, equivalent to the strict convexity of F at any steady state of subcritical mass, which heuristically explains the exponential speed of convergence.