arXiv:1509.03124 Abstract | arXiv Analytics

arXiv:1509.03124 [math.AP]Abstract References Reviews Resources

A continuum model for nematic alignment of self-propelled particles

Published 2015-09-10Version 1

A continuum model for a population of self-propelled particles interacting through nematic alignment is derived from an individual-based model. The methodology consists of introducing a hydrodynamic scaling of the corresponding mean-field kinetic equation. The resulting perturbation problem is solved thanks to the concept of generalized collision invariants. It yields a hyperbolic but non-conservative system of equations for the nematic mean direction of the flow and the densities of particles flowing parallel or anti-parallel to this mean direction. Diffusive terms are introduced under a weakly non-local interaction assumption and the diffusion coefficient is proven to be positive. An application to the modeling of myxobacteria is outlined.

Categories: math.AP, q-bio.CB

Subjects: 35L60, 35K55, 35Q80, 82C05, 82C22, 82C70, 92D50

Keywords: continuum model, nematic alignment, self-propelled particles, weakly non-local interaction assumption, corresponding mean-field kinetic equation

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