Ion Concentration Polarization by Bifurcated Current Path

Overview

Journal Sci Rep

Specialty Science

Date 2017 Jul 13

PMID 28698651

Citations 10

Authors

Junsuk Kim

Inhee Cho

Hyomin Lee

Sung Jae Kim

Affiliations

Soon will be listed here.

Abstract

Ion concentration polarization (ICP) is a fundamental electrokinetic process that occurs near a perm-selective membrane under dc bias. Overall process highly depends on the current transportation mechanisms such as electro-convection, surface conduction and diffusioosmosis and the fundamental characteristics can be significantly altered by external parameters, once the permselectivity was fixed. In this work, a new ICP device with a bifurcated current path as for the enhancement of the surface conduction was fabricated using a polymeric nanoporous material. It was protruded to the middle of a microchannel, while the material was exactly aligned at the interface between two microchannels in a conventional ICP device. Rigorous experiments revealed out that the propagation of ICP layer was initiated from the different locations of the protruded membrane according to the dominant current path which was determined by a bulk electrolyte concentration. Since the enhancement of surface conduction maintained the stability of ICP process, a strong electrokinetic flow associated with the amplified electric field inside ICP layer was significantly suppressed over the protruded membrane even at condensed limit. As a practical example of utilizing the protruded device, we successfully demonstrated a non-destructive micro/nanofluidic preconcentrator of fragile cellular species (i.e. red blood cells).

Citing Articles

Microvalve-Based Tunability of Electrically Driven Ion Transport through a Microfluidic System with an Ion-Exchange Membrane.

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Continuous Submicron Particle Separation Via Vortex-Enhanced Ionic Concentration Polarization: A Numerical Investigation.

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Simulation and Experimental Study of Ion Concentration Polarization Induced Electroconvective Vortex and Particle Movement.

Yoon J, Cho Y, Kim J, Kim H, Na K, Lee J Micromachines (Basel). 2021; 12(8).

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Eco friendly nanofluidic platforms using biodegradable nanoporous materials.

Park S, Hong S, Kim J, Son S, Lee H, Kim S Sci Rep. 2021; 11(1):3804.

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