Acoustophoresis in polymer-based microfluidic devices: Modeling and experimental validation

Fabian Lickert; Mathias Ohlin; Henrik Bruus; Pelle Ohlsson

doi:10.1121/10.0005113

Acoustophoresis in polymer-based microfluidic devices: Modeling and experimental validation

Fabian Lickert
, Mathias Ohlin
, Henrik Bruus^*
, Pelle Ohlsson

^*Corresponding author for this work

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Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

A finite-element model is presented for numerical simulation in three dimensions of acoustophoresis of suspended microparticles in a microchannel embedded in a polymer chip and driven by an attached piezoelectric transducer at MHz frequencies. In accordance with the recently introduced principle of whole-system ultrasound resonances, an optimal resonance mode is identified that is related to an acoustic resonance of the combined transducer-chip-channel system and not to the conventional pressure half-wave resonance of the microchannel. The acoustophoretic action in the microchannel is of comparable quality and strength to conventional silicon-glass or pure glass devices. The numerical predictions are validated by acoustic focusing experiments on 5-μm-diameter polystyrene particles suspended inside a microchannel, which was milled into a polymethylmethacrylate chip. The system was driven anti-symmetrically by a piezoelectric transducer, driven by a 30-V peak-to-peak alternating voltage in the range from 0.5 to 2.5 MHz, leading to acoustic energy densities of 13 J/m³ and particle focusing times of 6.6 s.

Original language	English
Journal	Journal of the Acoustical Society of America
Volume	149
Issue number	6
Pages (from-to)	4281-4291
ISSN	0001-4966
DOIs	https://doi.org/10.1121/10.0005113
Publication status	Published - 2021

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Funding Information:
This work is part of the Eureka Eurostars-2 joint programme E!113461 AcouPlast project funded by Innovation Fund Denmark, Grant No. 9046-00127B, and Vinnova, Sweden’s Innovation Agency, Grant No. 2019–04500, with co-funding from the European Union Horizon 2020 Research and Innovation Programme.

Publisher Copyright:
© 2021 Acoustical Society of America.

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title = "Acoustophoresis in polymer-based microfluidic devices: Modeling and experimental validation",

abstract = "A finite-element model is presented for numerical simulation in three dimensions of acoustophoresis of suspended microparticles in a microchannel embedded in a polymer chip and driven by an attached piezoelectric transducer at MHz frequencies. In accordance with the recently introduced principle of whole-system ultrasound resonances, an optimal resonance mode is identified that is related to an acoustic resonance of the combined transducer-chip-channel system and not to the conventional pressure half-wave resonance of the microchannel. The acoustophoretic action in the microchannel is of comparable quality and strength to conventional silicon-glass or pure glass devices. The numerical predictions are validated by acoustic focusing experiments on 5-μm-diameter polystyrene particles suspended inside a microchannel, which was milled into a polymethylmethacrylate chip. The system was driven anti-symmetrically by a piezoelectric transducer, driven by a 30-V peak-to-peak alternating voltage in the range from 0.5 to 2.5 MHz, leading to acoustic energy densities of 13 J/m3 and particle focusing times of 6.6 s.",

author = "Fabian Lickert and Mathias Ohlin and Henrik Bruus and Pelle Ohlsson",

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T1 - Acoustophoresis in polymer-based microfluidic devices

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AU - Lickert, Fabian

AU - Ohlin, Mathias

AU - Bruus, Henrik

AU - Ohlsson, Pelle

N1 - Funding Information: This work is part of the Eureka Eurostars-2 joint programme E!113461 AcouPlast project funded by Innovation Fund Denmark, Grant No. 9046-00127B, and Vinnova, Sweden’s Innovation Agency, Grant No. 2019–04500, with co-funding from the European Union Horizon 2020 Research and Innovation Programme. Publisher Copyright: © 2021 Acoustical Society of America.

PY - 2021

Y1 - 2021

N2 - A finite-element model is presented for numerical simulation in three dimensions of acoustophoresis of suspended microparticles in a microchannel embedded in a polymer chip and driven by an attached piezoelectric transducer at MHz frequencies. In accordance with the recently introduced principle of whole-system ultrasound resonances, an optimal resonance mode is identified that is related to an acoustic resonance of the combined transducer-chip-channel system and not to the conventional pressure half-wave resonance of the microchannel. The acoustophoretic action in the microchannel is of comparable quality and strength to conventional silicon-glass or pure glass devices. The numerical predictions are validated by acoustic focusing experiments on 5-μm-diameter polystyrene particles suspended inside a microchannel, which was milled into a polymethylmethacrylate chip. The system was driven anti-symmetrically by a piezoelectric transducer, driven by a 30-V peak-to-peak alternating voltage in the range from 0.5 to 2.5 MHz, leading to acoustic energy densities of 13 J/m3 and particle focusing times of 6.6 s.

AB - A finite-element model is presented for numerical simulation in three dimensions of acoustophoresis of suspended microparticles in a microchannel embedded in a polymer chip and driven by an attached piezoelectric transducer at MHz frequencies. In accordance with the recently introduced principle of whole-system ultrasound resonances, an optimal resonance mode is identified that is related to an acoustic resonance of the combined transducer-chip-channel system and not to the conventional pressure half-wave resonance of the microchannel. The acoustophoretic action in the microchannel is of comparable quality and strength to conventional silicon-glass or pure glass devices. The numerical predictions are validated by acoustic focusing experiments on 5-μm-diameter polystyrene particles suspended inside a microchannel, which was milled into a polymethylmethacrylate chip. The system was driven anti-symmetrically by a piezoelectric transducer, driven by a 30-V peak-to-peak alternating voltage in the range from 0.5 to 2.5 MHz, leading to acoustic energy densities of 13 J/m3 and particle focusing times of 6.6 s.

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DO - 10.1121/10.0005113

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SN - 0001-4966

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JO - Journal of the Acoustical Society of America

JF - Journal of the Acoustical Society of America

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ER -

Acoustophoresis in polymer-based microfluidic devices: Modeling and experimental validation

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