Critical dynamics of self-gravitating Langevin particles and bacterial populations

Abstract

We study the critical dynamics of the generalized Smoluchowski-Poisson system (for self-gravitating Langevin particles) or generalized Keller-Segel model (for the chemotaxis of bacterial populations). These models [Chavanis & Sire, PRE, 69, 016116 (2004)] are based on generalized stochastic processes leading to the Tsallis statistics. The equilibrium states correspond to polytropic configurations with index n similar to polytropic stars in astrophysics. At the critical index n3=d/(d-2) (where d 2 is the dimension of space), there exists a critical temperature c (for a given mass) or a critical mass Mc (for a given temperature). For >c or M<Mc the system tends to an incomplete polytrope confined by the box (in a bounded domain) or evaporates (in an unbounded domain). For <c or M>Mc the system collapses and forms, in a finite time, a Dirac peak containing a finite fraction Mc of the total mass surrounded by a halo. This study extends the critical dynamics of the ordinary Smoluchowski-Poisson system and Keller-Segel model in d=2 corresponding to isothermal configurations with n3 +∞. We also stress the analogy between the limiting mass of white dwarf stars (Chandrasekhar's limit) and the critical mass of bacterial populations in the generalized Keller-Segel model of chemotaxis.