Dynamics of magnetic self-propelled particles in a harmonic trap

TL;DR

This study investigates the complex behaviors of magnetic self-propelled particles confined in harmonic traps, revealing diverse metastable states influenced by particle number, activity, and magnetic interactions, with implications for active matter systems.

Contribution

It introduces magnetic self-propelled particles with magnetic dipoles, combining experimental and numerical analysis to explore their collective states in harmonic confinement, highlighting the role of magnetic interactions.

Findings

Diverse metastable configurations such as chains, clusters, and vortices.

Particle number, activity, and magnetic-harmonic potential balance influence metastability.

Numerical predictions align with experimental observations, emphasizing magnetic interactions.

Abstract

Artificial active particles, exemplified by Hexbugs (HB), serve as valuable tools for investigating the intricate dynamics of active matter systems. Leveraging their stochastic motion, Hexbugs provides an excellent experimental model. In this study, we utilize Hexbugs equipped with disk-like armor and embedded magnetic dipoles, transforming them into Magnetic Self-Propelled Particles (MSPP). We explore the emergence of collective and stationary states numerically and experimentally by confining these MSPPs within a parabolic domain acting as a harmonic potential. Our findings unveil a diverse range of metastable configurations intricately linked to the complex dynamics inherent in the system. We discern that particle number, activity, and the balance between magnetic and harmonic potential strengths predominantly influence the metastability of these structures. By employing these parameters as control factors, we compare and contrast the behavior of MSPPs with disk-like magnetic Active Brownian Particles (ABPs) in the overdamped limit of vanishing inertia. Our numerical predictions reproduce most of the experimental observations, highlighting the crucial role of magnetic dipole interactions in developing novel configurations for active particles within parabolic domains. These configurations include chains, clusters, and vortex formations characterized by a specific pattern in the particle spatial distribution. Notably, we observe that the influence of inertia is not fundamental in generating metastable configurations in these confined systems. Instead, the particle's shape, activity, and orientation are dominant factors. This comparative analysis provides insights into the distinctive features and dynamics of MSPP within confined environments, shedding light on the role of short-range polar interactions.