Size-dependent control of colloid transport via solute gradients in dead-end channels

Size-dependent control of colloid transport via solute gradients in dead-end channels

Transport of colloids in dead-end channels is involved in widespread applications including drug delivery and underground oil and gas recovery. In such geometries, Brownian motion may be considered as the sole mechanism that enables transport of colloidal particles into or out of the channels, but i...

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Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 113; no. 2; pp. 257 - 261
Main Authors: Shin, Sangwoo, Um, Eujin, Sabass, Benedikt, Ault, Jesse T., Rahimi, Mohammad, Warren, Patrick B., Stone, Howard A.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 12-01-2016
National Acad Sciences
Subjects:
Brownian motion
Dispersion
Geometry
Particle physics
Physical Sciences
Solute movement
Solution chemistry
solute gradient
colloid
diffusiophoresis
size effect
dead-end channel
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Summary:Transport of colloids in dead-end channels is involved in widespread applications including drug delivery and underground oil and gas recovery. In such geometries, Brownian motion may be considered as the sole mechanism that enables transport of colloidal particles into or out of the channels, but it is, unfortunately, an extremely inefficient transport mechanism for microscale particles. Here, we explore the possibility of diffusiophoresis as a means to control the colloid transport in dead-end channels by introducing a solute gradient. We demonstrate that the transport of colloidal particles into the dead-end channels can be either enhanced or completely prevented via diffusiophoresis. In addition, we show that size-dependent diffusiophoretic transport of particles can be achieved by considering a finite Debye layer thickness effect, which is commonly ignored. A combination of diffusiophoresis and Brownian motion leads to a strong size-dependent focusing effect such that the larger particles tend to concentrate more and reside deeper in the channel. Our findings have implications for all manners of controlled release processes, especially for site-specific delivery systems where localized targeting of particles with minimal dispersion to the nontarget area is essential.
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Edited by Herbert Levine, Rice University, Houston, TX, and approved November 17, 2015 (received for review June 11, 2015)
Author contributions: S.S., P.B.W., and H.A.S. designed research; S.S., E.U., B.S., J.T.A., M.R., P.B.W., and H.A.S. performed research; S.S., E.U., B.S., J.T.A., P.B.W., and H.A.S. analyzed data; and S.S., P.B.W., and H.A.S. wrote the paper.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1511484112