Issue 9, 2020

Dynamical self-assembly of dipolar active Brownian particles in two dimensions

Abstract

Based on Brownian Dynamics (BD) simulations, we study the dynamical self-assembly of active Brownian particles with dipole–dipole interactions, stemming from a permanent point dipole at the particle center. The propulsion direction of each particle is chosen to be parallel to its dipole moment. We explore a wide range of motilities and dipolar coupling strengths and characterize the corresponding behavior based on several order parameters. At low densities and low motilities, the most important structural phenomenon is the aggregation of the dipolar particles into chains. Upon increasing the particle motility, these chain-like structures break, and the system transforms into a weakly correlated isotropic fluid. At high densities, we observe that the motility-induced phase separation is strongly suppressed by the dipolar coupling. Once the dipolar coupling dominates the thermal energy, the phase separation disappears, and the system rather displays a flocking state, where particles form giant clusters and move collective along one direction. We provide arguments for the emergence of the flocking behavior, which is absent in the passive dipolar system.

Graphical abstract: Dynamical self-assembly of dipolar active Brownian particles in two dimensions

Associated articles

Article information

Article type
Paper
Submitted
31 Jul 2019
Accepted
28 Nov 2019
First published
24 Feb 2020
This article is Open Access
Creative Commons BY license

Soft Matter, 2020,16, 2208-2223

Dynamical self-assembly of dipolar active Brownian particles in two dimensions

G. Liao, C. K. Hall and S. H. L. Klapp, Soft Matter, 2020, 16, 2208 DOI: 10.1039/C9SM01539F

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