Geometric pumping in autophoretic channels

Sebastien Michelin; Thomas Montenegro-Johnson; Gabriele De Canio; Nicolas Lobato-Dauzier; Eric Lauga

doi:10.1039/C5SM00718F

Geometric pumping in autophoretic channels

Sebastien Michelin, Thomas Montenegro-Johnson, Gabriele De Canio, Nicolas Lobato-Dauzier, Eric Lauga

Mathematics

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17 Citations (Scopus)

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Abstract

Many microfluidic devices use macroscopic pressure differentials to overcome viscous friction and generate flows in microchannels. In this work, we investigate how the chemical and geometric properties of the channel walls can drive a net flow by exploiting the autophoretic slip flows induced along active walls by local concentration gradients of a solute species. We show that chemical patterning of the wall is not required to generate and control a net flux within the channel, rather channel geometry alone is sufficient. Using numerical simulations, we determine how geometric characteristics of the wall influence channel flow rate, and confirm our results analytically in the asymptotic limit of lubrication theory.

Original language	English
Pages (from-to)	5804-5811
Journal	Soft Matter
Volume	11
Issue number	29
DOIs	https://doi.org/10.1039/C5SM00718F
Publication status	Published - 7 May 2015

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10.1039/C5SM00718FLicence: None: All rights reserved

Michelin_et_al_Geometric_pumping_Soft_Matter_2015Submitted manuscript, 4.09 MBLicence: None: All rights reserved

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abstract = "Many microfluidic devices use macroscopic pressure differentials to overcome viscous friction and generate flows in microchannels. In this work, we investigate how the chemical and geometric properties of the channel walls can drive a net flow by exploiting the autophoretic slip flows induced along active walls by local concentration gradients of a solute species. We show that chemical patterning of the wall is not required to generate and control a net flux within the channel, rather channel geometry alone is sufficient. Using numerical simulations, we determine how geometric characteristics of the wall influence channel flow rate, and confirm our results analytically in the asymptotic limit of lubrication theory.",

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AU - Michelin, Sebastien

AU - Montenegro-Johnson, Thomas

AU - De Canio, Gabriele

AU - Lobato-Dauzier, Nicolas

AU - Lauga, Eric

PY - 2015/5/7

Y1 - 2015/5/7

N2 - Many microfluidic devices use macroscopic pressure differentials to overcome viscous friction and generate flows in microchannels. In this work, we investigate how the chemical and geometric properties of the channel walls can drive a net flow by exploiting the autophoretic slip flows induced along active walls by local concentration gradients of a solute species. We show that chemical patterning of the wall is not required to generate and control a net flux within the channel, rather channel geometry alone is sufficient. Using numerical simulations, we determine how geometric characteristics of the wall influence channel flow rate, and confirm our results analytically in the asymptotic limit of lubrication theory.

AB - Many microfluidic devices use macroscopic pressure differentials to overcome viscous friction and generate flows in microchannels. In this work, we investigate how the chemical and geometric properties of the channel walls can drive a net flow by exploiting the autophoretic slip flows induced along active walls by local concentration gradients of a solute species. We show that chemical patterning of the wall is not required to generate and control a net flux within the channel, rather channel geometry alone is sufficient. Using numerical simulations, we determine how geometric characteristics of the wall influence channel flow rate, and confirm our results analytically in the asymptotic limit of lubrication theory.

U2 - 10.1039/C5SM00718F

DO - 10.1039/C5SM00718F

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SN - 1744-683X

VL - 11

SP - 5804

EP - 5811

JO - Soft Matter

JF - Soft Matter

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ER -

Geometric pumping in autophoretic channels

Abstract

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