Self-organized Clusters in Diffusive Run-and-Tumble Processes
Abstract
We analyze a simplistic model for run-and-tumble dynamics, motivated by observations of complex spatio-temporal patterns in colonies of myxobacteria. In our model, agents run with fixed speed either left or right, and agents turn with a density-dependent nonlinear turning rate, in addition to diffusive Brownian motion. We show how a very simple nonlinearity in the turning rate can mediate the formation of self-organized stationary clusters and fronts. Phenomenologically, we demonstrate the formation of barriers, where high concentrations of agents at the boundary of a cluster, moving towards the center of a cluster, prevent the agents caught in the cluster from escaping. Mathematically, we analyze stationary solutions in a four-dimensional ODE with a conserved quantity and a reversibility symmetry, using a combination of bifurcation methods, geometric arguments, and numerical continuation. We also present numerical results on the temporal stability of the solutions found here.
Cite
@article{arxiv.1712.00112,
title = {Self-organized Clusters in Diffusive Run-and-Tumble Processes},
author = {Patrick Flynn and Quinton Neville and Arnd Scheel},
journal= {arXiv preprint arXiv:1712.00112},
year = {2017}
}
Comments
18 pages