📝 SummarXiv

Abstract

Field induced assembly of reconfigurable structures with complex hierarchical configurations has recently become an area of intense research with the promise for exciting applications in programmable self-assembly and nano/microstructure fabrication. While a wide variety of structures, from crystals to glasses, to chains and oligomers have been produced by activating colloidal particles with electric and magnetic fields, a combined approach utilizing the capabilities of multiple field types offers a richer parameter space, enabling precise structural control and a higher degree of reconfigurability. Here we demonstrate the assembly of complex hierarchical colloidal superstructures using an electric field (AC) and magnetic field (DC) combination. In our chosen frequency regime, dipolar (magnetic and electric) and electrohydrodynamic interactions are comparable, leading to a rich phase space with a wide number of configurations which are tunable by relatively small changes of the field parameters. This is in contrast to the existing small number of studies on multi-field induced assembly that work in size and frequency regimes where the dominant mechanism is dipolar interaction induced assembly. We show that depending upon the direction and frequency of the applied fields, there can be three possibilities in structure formation: a) a cooperation among the fields b) a competition among the fields and c) hierarchical reorganization in which micrometer-sized particles form chains that are part of larger clusters or 'domains' spanning tens of micrometers. This versatile, easy to set up and fully reconfigurable approach of multi-field induced structure formation opens up new opportunities for bottom-up fabrication of smart materials, switchable photonic crystals, and modular microswimmers for targeted drug delivery and environmental remediation.