TY - JOUR
T1 - Engineering fluid flow using sequenced microstructures
AU - Amini, Hamed
AU - Sollier, Elodie
AU - Masaeli, Mahdokht
AU - Xie, Yu
AU - Ganapathysubramanian, Baskar
AU - Stone, Howard A.
AU - Di Carlo, Dino
N1 - Funding Information:
We thank Patrick Sandoz for his help with solution exchange experiments and Eric Tsang for his helpful advice with the Tecan Plate Reader. We would like to thank Dr M. Schibler and the California NanoSystems Institute Advanced Light Microscopy Core Facility for their assistance with the confocal studies. This work is partially supported by National Science Foundation Grant 0930501. Y.X. and B.G. were supported in part by NSF1149365. B.G. and Y.X. thank XSEDE for computational resources via TG-CTS110007.
PY - 2013
Y1 - 2013
N2 - Controlling the shape of fluid streams is important across scales: from industrial processing to control of biomolecular interactions. Previous approaches to control fluid streams have focused mainly on creating chaotic flows to enhance mixing. Here we develop an approach to apply order using sequences of fluid transformations rather than enhancing chaos. We investigate the inertial flow deformations around a library of single cylindrical pillars within a microfluidic channel and assemble these net fluid transformations to engineer fluid streams. As these transformations provide a deterministic mapping of fluid elements from upstream to downstream of a pillar, we can sequentially arrange pillars to apply the associated nested maps and, therefore, create complex fluid structures without additional numerical simulation. To show the range of capabilities, we present sequences that sculpt the cross-sectional shape of a stream into complex geometries, move and split a fluid stream, perform solution exchange and achieve particle separation. A general strategy to engineer fluid streams into a broad class of defined configurations in which the complexity of the nonlinear equations of fluid motion are abstracted from the user is a first step to programming streams of any desired shape, which would be useful for biological, chemical and materials automation.
AB - Controlling the shape of fluid streams is important across scales: from industrial processing to control of biomolecular interactions. Previous approaches to control fluid streams have focused mainly on creating chaotic flows to enhance mixing. Here we develop an approach to apply order using sequences of fluid transformations rather than enhancing chaos. We investigate the inertial flow deformations around a library of single cylindrical pillars within a microfluidic channel and assemble these net fluid transformations to engineer fluid streams. As these transformations provide a deterministic mapping of fluid elements from upstream to downstream of a pillar, we can sequentially arrange pillars to apply the associated nested maps and, therefore, create complex fluid structures without additional numerical simulation. To show the range of capabilities, we present sequences that sculpt the cross-sectional shape of a stream into complex geometries, move and split a fluid stream, perform solution exchange and achieve particle separation. A general strategy to engineer fluid streams into a broad class of defined configurations in which the complexity of the nonlinear equations of fluid motion are abstracted from the user is a first step to programming streams of any desired shape, which would be useful for biological, chemical and materials automation.
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U2 - 10.1038/ncomms2841
DO - 10.1038/ncomms2841
M3 - Article
C2 - 23652014
AN - SCOPUS:84878603840
SN - 2041-1723
VL - 4
JO - Nature communications
JF - Nature communications
M1 - 1826
ER -