Particle manipulation using 3D ac electro-osmotic micropumps

Wolfgang Hilber; Bernhard Weiß; Miro Mikolasek; Roman Holly; Kurt Hingerl; Bernhard Jakoby

doi:10.1088/0960-1317/18/6/064016

Particle manipulation using 3D ac electro-osmotic micropumps

Wolfgang Hilber, Bernhard Weiß, Miro Mikolasek, Roman Holly, Kurt Hingerl, Bernhard Jakoby

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

Abstract

We present a novel mechanism of particle manipulation in alternating-current (ac)- driven electro-osmotic micropumps, utilizing the tunable ratio of viscous drag, inertial and dielectrophoretic forces. The latter are induced by three-dimensional (3D) stepped electrode arrays in the channel, which are driven by ac voltages enabling so-called 3D-ac-electro-osmotic pumping, as has been proposed recently. Due to size- and density-dependent differences in polarizability, targeted particles in the fluid stream can be slowed down or even pinned above the electrode structures solely by adjusting the operation parameters of the pump. Hence the presented device, fabricated in SU-8/glass technology, enables simultaneous pumping and manipulation of particles in suspension.

Original language	English
Article number	064016
Pages (from-to)	064016 (6pp)
Number of pages	6
Journal	Journal of Micromechanics and Microengineering
Volume	18
Issue number	6
DOIs	https://doi.org/10.1088/0960-1317/18/6/064016
Publication status	Published - May 2008

Fields of science

203017 Micromechanics

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10.1088/0960-1317/18/6/064016

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abstract = "We present a novel mechanism of particle manipulation in alternating-current (ac)- driven electro-osmotic micropumps, utilizing the tunable ratio of viscous drag, inertial and dielectrophoretic forces. The latter are induced by three-dimensional (3D) stepped electrode arrays in the channel, which are driven by ac voltages enabling so-called 3D-ac-electro-osmotic pumping, as has been proposed recently. Due to size- and density-dependent differences in polarizability, targeted particles in the fluid stream can be slowed down or even pinned above the electrode structures solely by adjusting the operation parameters of the pump. Hence the presented device, fabricated in SU-8/glass technology, enables simultaneous pumping and manipulation of particles in suspension.",

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T1 - Particle manipulation using 3D ac electro-osmotic micropumps

AU - Hilber, Wolfgang

AU - Weiß, Bernhard

AU - Mikolasek, Miro

AU - Holly, Roman

AU - Hingerl, Kurt

AU - Jakoby, Bernhard

PY - 2008/5

Y1 - 2008/5

N2 - We present a novel mechanism of particle manipulation in alternating-current (ac)- driven electro-osmotic micropumps, utilizing the tunable ratio of viscous drag, inertial and dielectrophoretic forces. The latter are induced by three-dimensional (3D) stepped electrode arrays in the channel, which are driven by ac voltages enabling so-called 3D-ac-electro-osmotic pumping, as has been proposed recently. Due to size- and density-dependent differences in polarizability, targeted particles in the fluid stream can be slowed down or even pinned above the electrode structures solely by adjusting the operation parameters of the pump. Hence the presented device, fabricated in SU-8/glass technology, enables simultaneous pumping and manipulation of particles in suspension.

AB - We present a novel mechanism of particle manipulation in alternating-current (ac)- driven electro-osmotic micropumps, utilizing the tunable ratio of viscous drag, inertial and dielectrophoretic forces. The latter are induced by three-dimensional (3D) stepped electrode arrays in the channel, which are driven by ac voltages enabling so-called 3D-ac-electro-osmotic pumping, as has been proposed recently. Due to size- and density-dependent differences in polarizability, targeted particles in the fluid stream can be slowed down or even pinned above the electrode structures solely by adjusting the operation parameters of the pump. Hence the presented device, fabricated in SU-8/glass technology, enables simultaneous pumping and manipulation of particles in suspension.

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DO - 10.1088/0960-1317/18/6/064016

M3 - Article

SN - 0960-1317

VL - 18

SP - 064016 (6pp)

JO - Journal of Micromechanics and Microengineering

JF - Journal of Micromechanics and Microengineering

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ER -

Particle manipulation using 3D ac electro-osmotic micropumps

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Dynamic capillary systems towards disposable fluid probes

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Particle manipulation using 3D ac electro-osmotic micropumps

Abstract

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Dynamic capillary systems towards disposable fluid probes

Cite this