Issue 24, 2018

Electrothermal based active control of ion transport in a microfluidic device with an ion-permselective membrane

Abstract

The ability to induce regions of high and low ionic concentrations adjacent to a permselective membrane or a nanochannel subject to an externally applied electric field (a phenomenon termed concentration-polarization) has been used for a broad spectrum of applications ranging from on-chip desalination, bacteria filtration to biomolecule preconcentration. But these applications have been limited by the ability to control the length of the diffusion layer that is commonly indirectly prescribed by the fixed geometric and surface properties of a nanofluidic system. Here, we demonstrate that the depletion layer can be dynamically varied by inducing controlled electrothermal flow driven by the interaction of temperature gradients with the applied electric field. To this end, a series of microscale heaters, which can be individually activated on demand are embedded at the bottom of the microchannel and the relationship between their activation and ionic concentration is characterized. Such spatio-temporal control of the diffusion layer can be used to enhance on-chip electro-dialysis by producing shorter depletion layers, to dynamically reduce the microchannel resistance relative to that of the nanochannel for nanochannel based (bio)sensing, to generate current rectification reminiscent of a diode like behavior and control the location of the preconcentrated plug of analytes or the interface of brine and desalted streams.

Graphical abstract: Electrothermal based active control of ion transport in a microfluidic device with an ion-permselective membrane

Supplementary files

Article information

Article type
Paper
Submitted
22 Mar 2018
Accepted
16 May 2018
First published
13 Jun 2018

Nanoscale, 2018,10, 11633-11641

Electrothermal based active control of ion transport in a microfluidic device with an ion-permselective membrane

S. Park and G. Yossifon, Nanoscale, 2018, 10, 11633 DOI: 10.1039/C8NR02389A

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