Issue 17, 2011

Micro-valve using induced-charge electrokinetic motion of Janus particle

Abstract

A new micro-valve using the electrokinetic motion of a Janus particle is introduced in this paper. A Janus particle with a conducting hemisphere and a non-conducting hemisphere is placed in a junction of several microchannels. Under an applied electric field, the induced-charge electrokinetic flow around the conducting side of the Janus particle forms vortices. The vortices push the particle moving forwards to block the entrance of a microchannel. By switching the direction of the applied electric field, the motion of the Janus particle can be changed to block different microchannels. This paper develops a theoretical model and conducts numerical simulations of the three-dimensional transient motion of the Janus particle. The results show that this Janus particle-based micro-valve is feasible for switching and controlling the flow rate in a microfluidic chip. This method is simple in comparison with other types of micro-valve methods. It is easy for fabrication, for operation control, and has a fast response time. To better understand the micro-valve functions, comparisons with a non-conducting particle and a fully conducting particle were made. Results proved that only a Janus particle can fulfill the requirements of such a micro-valve.

Graphical abstract: Micro-valve using induced-charge electrokinetic motion of Janus particle

Article information

Article type
Paper
Submitted
14 Mar 2011
Accepted
09 Jun 2011
First published
18 Jul 2011

Lab Chip, 2011,11, 2929-2940

Micro-valve using induced-charge electrokinetic motion of Janus particle

Y. Daghighi and D. Li, Lab Chip, 2011, 11, 2929 DOI: 10.1039/C1LC20229D

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