Title of article
Kinetic and hydrodynamic models of chemotactic aggregation
Author/Authors
Pierre-Henri Chavanis، نويسنده , , Clément Sire، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2007
Pages
24
From page
199
To page
222
Abstract
We derive general kinetic and hydrodynamic models of chemotactic aggregation that describe certain features of the morphogenesis of biological colonies (like bacteria, amoebae, endothelial cells or social insects). Starting from a stochastic model defined in terms of N coupled Langevin equations, we derive a nonlinear mean-field Fokker–Planck equation governing the evolution of the distribution function of the system in phase space. By taking the successive moments of this kinetic equation and using a local thermodynamic equilibrium condition, we derive a set of hydrodynamic equations involving a damping term. In the limit of small frictions, we obtain a hyperbolic model describing the formation of network patterns (filaments) and in the limit of strong frictions we obtain a parabolic model which is a generalization of the standard Keller–Segel model describing the formation of clusters (clumps). Our approach connects and generalizes several models introduced in the chemotactic literature. We discuss the analogy between bacterial colonies and self-gravitating systems and between the chemotactic collapse and the gravitational collapse (Jeans instability). We also show that the basic equations of chemotaxis are similar to nonlinear mean-field Fokker–Planck equations so that a notion of effective generalized thermodynamics can be developed.
Journal title
Physica A Statistical Mechanics and its Applications
Serial Year
2007
Journal title
Physica A Statistical Mechanics and its Applications
Record number
871977
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