Inertial focusing of spherical particles in curved microfluidic ducts at moderate Dean numbers

We examine the effect of Dean number on the inertial focusing of spherical particles suspended in flow through curved microfluidic ducts. Previous modelling of particle migration in curved ducts assumed the flow rate was small enough that a leading-order approximation of the background flow with res...

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Bibliographic Details
Published inJournal of fluid mechanics Vol. 957
Main Authors Harding, Brendan, Stokes, Yvonne M.
Format Journal Article
LanguageEnglish
Published Cambridge, UK Cambridge University Press 25.02.2023
Subjects
Approximation
Cross-sections
Ducts
Equilibrium
Flow rates
Flow velocity
Fluid flow
Induced drag
JFM Papers
Laboratories
Microfluidics
Ordinary differential equations
Perturbation
Reynolds number
Secondary flow
Velocity
Velocity distribution
Velocity profiles
Vortices
particle/fluid flow
microfluidics
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Summary:We examine the effect of Dean number on the inertial focusing of spherical particles suspended in flow through curved microfluidic ducts. Previous modelling of particle migration in curved ducts assumed the flow rate was small enough that a leading-order approximation of the background flow with respect to the Dean number produces a reasonable model. Herein, we extend our model to situations involving a moderate Dean number (in the microfluidics context) while the particle Reynolds number remains small. Variations in the Dean number cause a change in the axial velocity profile of the background flow which influences the inertial lift force on a particle. Simultaneously, changes in the cross-sectional velocity components of the background flow directly affect the secondary flow induced drag. In keeping the particle Reynolds number small, we continue to approximate the inertial lift force using a regular perturbation while capturing the subtle effects from the modified background flow. This approach pushes the limits at which a regular perturbation is applicable to provide some insights into how variations in the Dean number influence particle focusing. Our results illustrate that, as the extrema in the background flow move towards the outside of edge of the cross-section with increasing Dean number, we observe a similar shift in the stable equilibria of some, but not all, particle sizes. This might be exploited to enhance the lateral separation of particles by size in a number of practical scenarios.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2023.43