Reduction of Taylor-Aris dispersion by lateral mixing for chromatographic applications

Eiko Westerbeek; Johan G. Bomer; Wouter Olthuis; Jan C.T. Eijkel; Wim De Malsche

doi:10.1039/d0lc00773k

Reduction of Taylor-Aris dispersion by lateral mixing for chromatographic applications

Eiko Westerbeek, Johan G. Bomer, Wouter Olthuis, Jan C.T. Eijkel, Wim De Malsche

Research output: Contribution to journal › Article › peer-review

19 Citations (Scopus)

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Abstract

Chromatographic columns are suffering from Taylor-Aris dispersion, especially for slowly diffusing molecules such as proteins. Since downscaling the channel size to reduce Taylor-Aris dispersion meets fundamental pressure limitations, new strategies are needed to further improve chromatography beyond its current limits. In this work we demonstrate a method to reduce Taylor-Aris dispersion by lateral mixing in a newly designed silicon AC-electroosmotic flow mixer. We obtained a reduction in κaris by a factor of three in a 40 μm × 20 μm microchannel, corresponding to a plate height gain of 2 to 3 under unretained conditions at low to high Pe values. We also demonstrate an improvement of a reverse-phase chromatographic separation of coumarins.

Original language	English
Pages (from-to)	3938-3947
Number of pages	10
Journal	Lab on a Chip
Volume	20
Issue number	21
DOIs	https://doi.org/10.1039/d0lc00773k
Publication status	Published - 7 Nov 2020

Keywords

AC-electric fields
Kinetic performance
flow
impedance
micro
Microelectrodes
Microchannel
Electrolytes
separations
channels

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10.1039/d0lc00773k

20200730_Reduction of Taylor-Aris dispersion by lateral mixing for chromatographic applications_V2_JE_wdm (004)_final_version
The author(s) opt to apply XI.196. § 2/1 book 1 “intellectuele eigendommen” of the Belgian Federal Code of Economic Law in order to obey funder requirements.

Cite this

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title = "Reduction of Taylor-Aris dispersion by lateral mixing for chromatographic applications",

abstract = "Chromatographic columns are suffering from Taylor-Aris dispersion, especially for slowly diffusing molecules such as proteins. Since downscaling the channel size to reduce Taylor-Aris dispersion meets fundamental pressure limitations, new strategies are needed to further improve chromatography beyond its current limits. In this work we demonstrate a method to reduce Taylor-Aris dispersion by lateral mixing in a newly designed silicon AC-electroosmotic flow mixer. We obtained a reduction in κaris by a factor of three in a 40 μm × 20 μm microchannel, corresponding to a plate height gain of 2 to 3 under unretained conditions at low to high Pe values. We also demonstrate an improvement of a reverse-phase chromatographic separation of coumarins.",

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doi = "10.1039/d0lc00773k",

language = "English",

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T1 - Reduction of Taylor-Aris dispersion by lateral mixing for chromatographic applications

AU - Westerbeek, Eiko

AU - Bomer, Johan G.

AU - Olthuis, Wouter

AU - Eijkel, Jan C.T.

AU - De Malsche, Wim

PY - 2020/11/7

Y1 - 2020/11/7

N2 - Chromatographic columns are suffering from Taylor-Aris dispersion, especially for slowly diffusing molecules such as proteins. Since downscaling the channel size to reduce Taylor-Aris dispersion meets fundamental pressure limitations, new strategies are needed to further improve chromatography beyond its current limits. In this work we demonstrate a method to reduce Taylor-Aris dispersion by lateral mixing in a newly designed silicon AC-electroosmotic flow mixer. We obtained a reduction in κaris by a factor of three in a 40 μm × 20 μm microchannel, corresponding to a plate height gain of 2 to 3 under unretained conditions at low to high Pe values. We also demonstrate an improvement of a reverse-phase chromatographic separation of coumarins.

AB - Chromatographic columns are suffering from Taylor-Aris dispersion, especially for slowly diffusing molecules such as proteins. Since downscaling the channel size to reduce Taylor-Aris dispersion meets fundamental pressure limitations, new strategies are needed to further improve chromatography beyond its current limits. In this work we demonstrate a method to reduce Taylor-Aris dispersion by lateral mixing in a newly designed silicon AC-electroosmotic flow mixer. We obtained a reduction in κaris by a factor of three in a 40 μm × 20 μm microchannel, corresponding to a plate height gain of 2 to 3 under unretained conditions at low to high Pe values. We also demonstrate an improvement of a reverse-phase chromatographic separation of coumarins.

KW - AC-electric fields

KW - Kinetic performance

KW - flow

KW - impedance

KW - micro

KW - Microelectrodes

KW - Microchannel

KW - Electrolytes

KW - separations

KW - channels

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U2 - 10.1039/d0lc00773k

DO - 10.1039/d0lc00773k

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EP - 3947

JO - Lab on a Chip

JF - Lab on a Chip

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Reduction of Taylor-Aris dispersion by lateral mixing for chromatographic applications

Abstract

Keywords

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SRP6: Strategic Research Programme: Exploiting the Advantages of Order and Geometrical Structure for a Greener Chemistry

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Reduction of Taylor-Aris dispersion by lateral mixing for chromatographic applications

Abstract

Keywords

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Projects

SRP6: Strategic Research Programme: Exploiting the Advantages of Order and Geometrical Structure for a Greener Chemistry

Cite this