Magnetically locked Janus particle clusters with orientation-dependent motion in AC electric fields

Active particles, or micromotors, locally dissipate energy to drive locomotion at small length scales. The type of trajectory is generally fixed and dictated by the geometry and composition of the particle, which can be challenging to tune using conventional fabrication procedures. Here, we report a simple, bottom-up method to magnetically assemble gold-coated polystyrene Janus particles into locked clusters that display diverse trajectories when stimulated by AC electric fields. The orientation of particles within each cluster gives rise to distinct modes of locomotion, including translational, rotational, trochoidal, helical, and orbital. We model this system using a simplified rigid beads model and demonstrate qualitative agreement between the predicted and experimentally observed cluster trajectories. Overall, this system provides a facile means to scalably create micromotors with a range of well-defined motions from discrete building blocks. Magnetically assembled Janus particles display orientation-dependent motions in AC electric fields. The regimes of motion are studied by experiments and modeling to understand and inform future microrobot design.

Automated summary

This study presents a method of magnetically assembling locked clusters of Janus particles, which display diverse trajectories when stimulated by AC electric fields. The orientation of particles within each cluster determines the different modes of locomotion. The predicted and experimentally observed cluster trajectories show qualitative agreement. This method provides a scalable way to create micromotors with a range of well-defined motions.