Long-range forces affecting equilibrium inertial focusing behavior in straight high aspect ratio microfluidic channels

The controlled and directed focusing of particles within flowing fluids is a problem of fundamental and technological significance. Microfluidic inertial focusing provides passive and precise lateral and longitudinal alignment of small particles without the need for external actuation or sheath flui...

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Bibliographic Details
Published in:Physics of fluids (1994) 2016-04, Vol.28 (4), p.043303-043303
Main Authors: Reece, Amy E., Oakey, John
Format: Article
Language:English
Subjects:
Actuation
ASPECT RATIO
BALANCES
CELL FLOW SYSTEMS
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
CONCENTRATION RATIO
CROSS SECTIONS
ENGINEERING
EQUILIBRIUM
Fluid dynamics
FLUID FLOW
FLUIDIC CONTROL DEVICES
FLUIDS
FOCUSING
GEOMETRY
High aspect ratio
PARTICLES
Physics
SCALING
Sheaths
Straight channels
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Summary:The controlled and directed focusing of particles within flowing fluids is a problem of fundamental and technological significance. Microfluidic inertial focusing provides passive and precise lateral and longitudinal alignment of small particles without the need for external actuation or sheath fluid. The benefits of inertial focusing have quickly enabled the development of miniaturized flow cytometers, size-selective sorting devices, and other high-throughput particle screening tools. Straight channel inertial focusing device design requires knowledge of fluid properties and particle-channel size ratio. Equilibrium behavior of inertially focused particles has been extensively characterized and the constitutive phenomena described by scaling relationships for straight channels of square and rectangular cross section. In concentrated particle suspensions, however, long-range hydrodynamic repulsions give rise to complex particle ordering that, while interesting and potentially useful, can also dramatically diminish the technique’s effectiveness for high-throughput particle handling applications. We have empirically investigated particle focusing behavior within channels of increasing aspect ratio and have identified three scaling regimes that produce varying degrees of geometrical ordering between focused particles. To explore the limits of inertial particle focusing and identify the origins of these long-range interparticle forces, we have explored equilibrium focusing behavior as a function of channel geometry and particle concentration. Experimental results for highly concentrated particle solutions identify equilibrium thresholds for focusing that scale weakly with concentration and strongly with channel geometry. Balancing geometry mediated inertial forces with estimates for interparticle repulsive forces now provide a complete picture of pattern formation among concentrated inertially focused particles and enhance our understanding of the fundamental limits of inertial focusing for technological applications.
ISSN:1070-6631
1089-7666
DOI:10.1063/1.4946829