Marangoni flow in micro-channels

Hye Jin Lee; David J. Fermín; Robert M. Corn; Hubert H. Girault

doi:10.1016/S1388-2481(99)00038-7

Marangoni flow in micro-channels

Hye Jin Lee, David J. Fermín, Robert M. Corn, Hubert H. Girault

Research output: Contribution to journal › Article › peer-review

23 Scopus citations

Abstract

A novel electrochemical method for driving fluids in micro-channels is presented. The principle is based upon the onset of Marangoni flow along the interface between an aqueous solution (mobile phase) and an organic electrolyte polymer gel coated on the inner walls of the micro-channel. The gradient of surface tension responsible for the fluid motion arises from local changes in the surface charge. The excess charge is determined by the ionisation of surfactant species at the gel coatingaqueous electrolyte interface which is effectively dependent on the Galvani potential difference. Potential differences of less than a volt between two closely spaced silver band electrodes along the micro-channel can generate zones of high and low surface tension, promoting the motion of the aqueous electrolyte.

Original language	English
Pages (from-to)	190-193
Number of pages	4
Journal	Electrochemistry Communications
Volume	1
Issue number	5
DOIs	https://doi.org/10.1016/S1388-2481(99)00038-7
State	Published - 1 May 1999

Keywords

Liquidpolymer gel interfaces
Marangoni flow
Micro-channel networks
Surfactant

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10.1016/S1388-2481(99)00038-7

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title = "Marangoni flow in micro-channels",

abstract = "A novel electrochemical method for driving fluids in micro-channels is presented. The principle is based upon the onset of Marangoni flow along the interface between an aqueous solution (mobile phase) and an organic electrolyte polymer gel coated on the inner walls of the micro-channel. The gradient of surface tension responsible for the fluid motion arises from local changes in the surface charge. The excess charge is determined by the ionisation of surfactant species at the gel coatingaqueous electrolyte interface which is effectively dependent on the Galvani potential difference. Potential differences of less than a volt between two closely spaced silver band electrodes along the micro-channel can generate zones of high and low surface tension, promoting the motion of the aqueous electrolyte.",

keywords = "Liquidpolymer gel interfaces, Marangoni flow, Micro-channel networks, Surfactant",

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T1 - Marangoni flow in micro-channels

AU - Lee, Hye Jin

AU - Fermín, David J.

AU - Corn, Robert M.

AU - Girault, Hubert H.

PY - 1999/5/1

Y1 - 1999/5/1

N2 - A novel electrochemical method for driving fluids in micro-channels is presented. The principle is based upon the onset of Marangoni flow along the interface between an aqueous solution (mobile phase) and an organic electrolyte polymer gel coated on the inner walls of the micro-channel. The gradient of surface tension responsible for the fluid motion arises from local changes in the surface charge. The excess charge is determined by the ionisation of surfactant species at the gel coatingaqueous electrolyte interface which is effectively dependent on the Galvani potential difference. Potential differences of less than a volt between two closely spaced silver band electrodes along the micro-channel can generate zones of high and low surface tension, promoting the motion of the aqueous electrolyte.

AB - A novel electrochemical method for driving fluids in micro-channels is presented. The principle is based upon the onset of Marangoni flow along the interface between an aqueous solution (mobile phase) and an organic electrolyte polymer gel coated on the inner walls of the micro-channel. The gradient of surface tension responsible for the fluid motion arises from local changes in the surface charge. The excess charge is determined by the ionisation of surfactant species at the gel coatingaqueous electrolyte interface which is effectively dependent on the Galvani potential difference. Potential differences of less than a volt between two closely spaced silver band electrodes along the micro-channel can generate zones of high and low surface tension, promoting the motion of the aqueous electrolyte.

KW - Liquidpolymer gel interfaces

KW - Marangoni flow

KW - Micro-channel networks

KW - Surfactant

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U2 - 10.1016/S1388-2481(99)00038-7

DO - 10.1016/S1388-2481(99)00038-7

M3 - Article

AN - SCOPUS:0001334054

SN - 1388-2481

VL - 1

SP - 190

EP - 193

JO - Electrochemistry Communications

JF - Electrochemistry Communications

IS - 5

ER -

Marangoni flow in micro-channels

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Keywords

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