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Characterization of electrothermal microfluidic tweezers (REP) in bio-relevant media

Characterization of electrothermal microfluidic tweezers (REP) in bio-relevant media
Characterization of electrothermal microfluidic tweezers (REP) in bio-relevant media
Rapid electrokinetic patterning (REP) has proven to be a powerful microfluidic tweezer that generates spatially and temporally specified microflow via electrothermal vortices. The ultra-small trapping forces on the scale of femtoNewtons exerted by REP, due to its viscous drag of the vortical flow on the trapped particles, attracts many potential bio-manipulation applications. We report, for the first time, use of isotonic sugar-based media to simulate bio-relevant environment for flow manipulation through REP. A DC field was introduced, in addition to the typical AC field, to enhance the vortical flow induced particle trapping performance. In this work, we study the effects of the magnitude and sign of the DC offset on the vortex characteristics. Results show that addition of the DC component in the electric field has a significant impact on the electrothermal micro-vortex and the electric double layer of the electrodes and the trapped particles. We also observe that an abrupt change in the DC offset destabilized the vortex and washed away some particles as the trap equilibrium re-established. However, the trap remained stable when the step change in the DC offset was smaller than ~500 mV.
Chen, Zhengwei
d888751a-1300-4ce4-9d0c-5a2a1075f102
Gupta, Kshitiz
726543ab-6767-46cb-89aa-db4ef808dfb7
Green, Nicolas G.
d9b47269-c426-41fd-a41d-5f4579faa581
Wereley, Steven T
b80225dd-e66c-4d34-9317-fcaf48e94677
Chen, Zhengwei
d888751a-1300-4ce4-9d0c-5a2a1075f102
Gupta, Kshitiz
726543ab-6767-46cb-89aa-db4ef808dfb7
Green, Nicolas G.
d9b47269-c426-41fd-a41d-5f4579faa581
Wereley, Steven T
b80225dd-e66c-4d34-9317-fcaf48e94677

Chen, Zhengwei, Gupta, Kshitiz, Green, Nicolas G. and Wereley, Steven T (2022) Characterization of electrothermal microfluidic tweezers (REP) in bio-relevant media. 75th Annual Meeting of the Division of Fluid Dynamics, Indiana Convention Center, Indianapolis, United States. 20 - 22 Nov 2022.

Record type: Conference or Workshop Item (Paper)

Abstract

Rapid electrokinetic patterning (REP) has proven to be a powerful microfluidic tweezer that generates spatially and temporally specified microflow via electrothermal vortices. The ultra-small trapping forces on the scale of femtoNewtons exerted by REP, due to its viscous drag of the vortical flow on the trapped particles, attracts many potential bio-manipulation applications. We report, for the first time, use of isotonic sugar-based media to simulate bio-relevant environment for flow manipulation through REP. A DC field was introduced, in addition to the typical AC field, to enhance the vortical flow induced particle trapping performance. In this work, we study the effects of the magnitude and sign of the DC offset on the vortex characteristics. Results show that addition of the DC component in the electric field has a significant impact on the electrothermal micro-vortex and the electric double layer of the electrodes and the trapped particles. We also observe that an abrupt change in the DC offset destabilized the vortex and washed away some particles as the trap equilibrium re-established. However, the trap remained stable when the step change in the DC offset was smaller than ~500 mV.

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More information

Published date: 21 November 2022
Venue - Dates: 75th Annual Meeting of the Division of Fluid Dynamics, Indiana Convention Center, Indianapolis, United States, 2022-11-20 - 2022-11-22

Identifiers

Local EPrints ID: 483737
URI: http://eprints.soton.ac.uk/id/eprint/483737
PURE UUID: 4157bde3-cb42-40cd-9ea7-a763ffabae80
ORCID for Nicolas G. Green: ORCID iD orcid.org/0000-0001-9230-4455

Catalogue record

Date deposited: 03 Nov 2023 18:04
Last modified: 18 Mar 2024 02:59

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Contributors

Author: Zhengwei Chen
Author: Kshitiz Gupta
Author: Nicolas G. Green ORCID iD
Author: Steven T Wereley

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