Mobile Microelectrodes: Towards active spatio-temporal control of the electric field and selective cargo assembly

TL;DR

This paper introduces a novel bottom-up approach using colloids as floating electrodes to dynamically control electric fields in microfluidic devices, enabling real-time, selective cargo assembly without complex patterning.

Contribution

It presents a new method for active electric field control in microfluidics using colloids as portable electrodes, replacing traditional top-down patterning techniques.

Findings

Colloids can induce strong, three-dimensional electric field gradients.

The system enables on-demand, label-free cargo assembly and transport.

Colloid polarization allows real-time reconfiguration of electric fields.

Abstract

With an eye towards next-generation, smart, micro/nanofluidic devices, capable of responding to external stimuli or changes in environment, we demonstrate a means to achieve dynamic control of the spatio-temporal properties of the electric field in a standardized microfluidic chamber. Typical top-down patterning, currently used to design the field distribution, is replaced by freely-suspended colloids which locally disturb the electric field from the bottom-up. Even under uniform forcing, polarization of the colloid induces the formation of strong, three-dimensional gradients at its surface - essentially repurposing it into a portable floating electrode whose precise location can be manipulated to reconfigure the electric field in real time. Focusing on active Janus colloids as a sample platform, we measure the strength of the induced gradients and highlight the advantages of a colloid-based system by revealing a prototype for an all-in-one cargo carrier, capable of on-demand, selective, label-free assembly and transport of micro/nano sized targets.