Emergent colloidal edge currents generated via exchange dynamics in a broken dimer state

TL;DR

This paper introduces a novel method to generate and control edge currents of microparticles using magnetic interactions and confinement, mimicking electronic orbit behaviors, with potential applications across various scientific fields.

Contribution

It presents a new approach to assemble and transport microparticles via magnetic modulation, creating collective edge currents through a field-synchronized exchange process.

Findings

Formation of rotating dimeric states and binary lattices.

Observation of collective edge currents due to exchange dynamics.

Analogy to electronic cyclotron and skipping orbits.

Abstract

Controlling the flow of matter down to micrometer-scale confinement is of central importance in materials and environmental sciences, with direct applications in nano-microfluidics, drug delivery and biothechnology. Currents of microparticles are usually generated with external field gradients of different nature [e.g., electric, magnetic, optical, thermal or chemical ones] which are difficult to control over spatially extended regions and samples. Here we demonstrate a general strategy to assemble and transport polarizable microparticles in fluid media through combination of confinement and magnetic dipolar interactions. We use a homogeneous magnetic modulation to assemble dispersed particles into rotating dimeric state and frustrated binary lattices, and generate collective edge currents which arise from a novel, field-synchronized particle exchange process. These dynamic states are similar to cyclotron and skipping orbits in electronic and molecular systems, thus paving the way toward understanding and engineering similar processes at different length scales across condensed matter.