Concentration profiles of ions and particles under hydrodynamic focusing in Y-shaped square microchannel

Abstract Three-dimensional ion and particle concentrations under hydrodynamic focusing in a Y-shaped square microchannel are numerically simulated to clarify the decrease of the ion concentration along the flow direction within the focused particle stream. The simulation model is theoretically gover...

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Main Authors: Norikazu Sato, Daisuke Kawashima, Masahiro Takei
Format: Article
Language:English
Published: Nature Publishing Group 2021-01-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-021-82259-4
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spelling doaj-2d273d57c3ff43968e600571f4ca2f0d2021-01-31T16:26:37ZengNature Publishing GroupScientific Reports2045-23222021-01-011111910.1038/s41598-021-82259-4Concentration profiles of ions and particles under hydrodynamic focusing in Y-shaped square microchannelNorikazu Sato0Daisuke Kawashima1Masahiro Takei2Sensing & Process Solution Division, JFE Techno-Research CorporationGraduate School of Science and Engineering, Chiba UniversityGraduate School of Science and Engineering, Chiba UniversityAbstract Three-dimensional ion and particle concentrations under hydrodynamic focusing in a Y-shaped square microchannel are numerically simulated to clarify the decrease of the ion concentration along the flow direction within the focused particle stream. The simulation model is theoretically governed by the laminar flow and advection–diffusion equations. The governing equations are solved by the finite volume method. The ion and particle concentration distributions at five cross sections after the confluence of the branch channels are analyzed in 30 cases in which the sheath to sample flow rate ratio Q sh /Q sam and the Reynolds number Re are varied as parameters. The results show that the decrease of the cross-sectional average ion concentration along the flow direction within the particle stream $$\overline{c}_{i}$$ c ¯ i is described by the diffusion length during the residence time with a characteristic velocity scale. In addition, the deformation of the particle stream due to inertial effects is described by a scaled Reynolds number that is a function of the flow rate ratio. The simulated particle stream thicknesses are validated by theory and a simple experiment. This paper reveals the relationship between the ion and particle concentrations and the dimensionless parameters for hydrodynamic focusing in the Y-shaped square microchannel under typical conditions.https://doi.org/10.1038/s41598-021-82259-4
collection DOAJ
language English
format Article
sources DOAJ
author Norikazu Sato
Daisuke Kawashima
Masahiro Takei
spellingShingle Norikazu Sato
Daisuke Kawashima
Masahiro Takei
Concentration profiles of ions and particles under hydrodynamic focusing in Y-shaped square microchannel
Scientific Reports
author_facet Norikazu Sato
Daisuke Kawashima
Masahiro Takei
author_sort Norikazu Sato
title Concentration profiles of ions and particles under hydrodynamic focusing in Y-shaped square microchannel
title_short Concentration profiles of ions and particles under hydrodynamic focusing in Y-shaped square microchannel
title_full Concentration profiles of ions and particles under hydrodynamic focusing in Y-shaped square microchannel
title_fullStr Concentration profiles of ions and particles under hydrodynamic focusing in Y-shaped square microchannel
title_full_unstemmed Concentration profiles of ions and particles under hydrodynamic focusing in Y-shaped square microchannel
title_sort concentration profiles of ions and particles under hydrodynamic focusing in y-shaped square microchannel
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2021-01-01
description Abstract Three-dimensional ion and particle concentrations under hydrodynamic focusing in a Y-shaped square microchannel are numerically simulated to clarify the decrease of the ion concentration along the flow direction within the focused particle stream. The simulation model is theoretically governed by the laminar flow and advection–diffusion equations. The governing equations are solved by the finite volume method. The ion and particle concentration distributions at five cross sections after the confluence of the branch channels are analyzed in 30 cases in which the sheath to sample flow rate ratio Q sh /Q sam and the Reynolds number Re are varied as parameters. The results show that the decrease of the cross-sectional average ion concentration along the flow direction within the particle stream $$\overline{c}_{i}$$ c ¯ i is described by the diffusion length during the residence time with a characteristic velocity scale. In addition, the deformation of the particle stream due to inertial effects is described by a scaled Reynolds number that is a function of the flow rate ratio. The simulated particle stream thicknesses are validated by theory and a simple experiment. This paper reveals the relationship between the ion and particle concentrations and the dimensionless parameters for hydrodynamic focusing in the Y-shaped square microchannel under typical conditions.
url https://doi.org/10.1038/s41598-021-82259-4
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AT daisukekawashima concentrationprofilesofionsandparticlesunderhydrodynamicfocusinginyshapedsquaremicrochannel
AT masahirotakei concentrationprofilesofionsandparticlesunderhydrodynamicfocusinginyshapedsquaremicrochannel
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