Wall repulsion during electrophoresis: testing the theory of concentration-polarization electro-osmosis
Wall repulsion during electrophoresis: testing the theory of concentration-polarization electro-osmosis
We experimentally study the repulsion of charged microscopic particles with the channel walls during electrophoresis in microfluidic devices. For low frequencies of the electric fields (< 10 kHz), this repulsion is mainly due to the hydrodynamic interaction caused by the flow vortices that arise from the slip velocity induced by the electric field on the particle surface, as shown in a recent publication [Fernandez-Mateo et al., Physical Review Letters, 128, 074501, (2022)]. The maximum slip velocity on the particle surface is inferred from measurements of wall-particle separation. Importantly, this procedure allows us to infer very small slip velocities that otherwise are too weak to be measured directly. Data at small electric field amplitudes (E0) agree with theoretical predictions using the model of Concentration Polarization Electroosmosis (CPEO), which has recently been proposed as the mechanism behind the flow vortices on the surface of the particles. Data for higher electric fields show that the predictions of the CPEO theory for weak electric fields are not valid beyond E0 ∼ 60 kV/m. Additionally, we also show that, for sufficiently strong electric fields, the quadrupolar flow structures become disrupted, leading to a weaker wall repulsion.
Fernandez-Mateo, Raul
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Morgan, Hywel
de00d59f-a5a2-48c4-a99a-1d5dd7854174
Ramos, Antonio
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Garcia-Sanchez, Pablo
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Fernandez-Mateo, Raul
f287538e-c53c-4208-b8bf-945b0966fd5f
Morgan, Hywel
de00d59f-a5a2-48c4-a99a-1d5dd7854174
Ramos, Antonio
b22a8818-ae06-4bc5-a10d-a503f5ad626a
Garcia-Sanchez, Pablo
11cec08e-0384-4ef6-a1b3-183c9b32c4ea
Fernandez-Mateo, Raul, Morgan, Hywel, Ramos, Antonio and Garcia-Sanchez, Pablo
(2023)
Wall repulsion during electrophoresis: testing the theory of concentration-polarization electro-osmosis.
Journal of Extracellular Biology.
(In Press)
Abstract
We experimentally study the repulsion of charged microscopic particles with the channel walls during electrophoresis in microfluidic devices. For low frequencies of the electric fields (< 10 kHz), this repulsion is mainly due to the hydrodynamic interaction caused by the flow vortices that arise from the slip velocity induced by the electric field on the particle surface, as shown in a recent publication [Fernandez-Mateo et al., Physical Review Letters, 128, 074501, (2022)]. The maximum slip velocity on the particle surface is inferred from measurements of wall-particle separation. Importantly, this procedure allows us to infer very small slip velocities that otherwise are too weak to be measured directly. Data at small electric field amplitudes (E0) agree with theoretical predictions using the model of Concentration Polarization Electroosmosis (CPEO), which has recently been proposed as the mechanism behind the flow vortices on the surface of the particles. Data for higher electric fields show that the predictions of the CPEO theory for weak electric fields are not valid beyond E0 ∼ 60 kV/m. Additionally, we also show that, for sufficiently strong electric fields, the quadrupolar flow structures become disrupted, leading to a weaker wall repulsion.
Text
Wall repulsion during electrophoresis Testing the theory of concentration polarization electro-osmosis
- Accepted Manuscript
More information
Accepted/In Press date: 8 January 2023
Identifiers
Local EPrints ID: 476143
URI: http://eprints.soton.ac.uk/id/eprint/476143
ISSN: 2768-2811
PURE UUID: f7379cf9-37b2-4bce-88aa-0f0ab41581e9
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Date deposited: 12 Apr 2023 16:53
Last modified: 17 Mar 2024 02:58
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Contributors
Author:
Raul Fernandez-Mateo
Author:
Hywel Morgan
Author:
Antonio Ramos
Author:
Pablo Garcia-Sanchez
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