Issue 21, 2019

Surface forces generated by the action of electric fields across liquid films

Abstract

We explore the force generation and surface interactions arising when electric fields are applied across fluid films. Using a surface force balance (SFB) we measure directly the force between two electrodes in crossed-cylinder geometry across dielectric and electrolytic fluids. In the case of dielectric films the field between the electrodes exerts a force which can be well explained using classic expressions and with no fitting parameters. However when the electrodes are separated by a film of electrolyte, an alternating electric field induces a force which diverges substantially from the calculated static response of the electrolyte. The magnitude of the force is larger than predicted, and the interaction can switch from attractive to repulsive. Furthermore, the approach to steady state in electrolyte takes place over 102–103 s which is very slow compared to both the charging and viscous timescales of the system. The non-trivial electrolyte response in AC electric fields, measured here directly, is likely to underlie several recent reports of unexpected and bifurcating forces driving colloids in AC fields. Our measurements suggest ways to control colloidal and soft matter using electric fields, as well as providing a direct measure of the length- and time-scales relevant in AC electrochemical and electrokinetic systems.

Graphical abstract: Surface forces generated by the action of electric fields across liquid films

Supplementary files

Article information

Article type
Paper
Submitted
21 ม.ค. 2562
Accepted
07 เม.ย. 2562
First published
25 เม.ย. 2562

Soft Matter, 2019,15, 4255-4265

Surface forces generated by the action of electric fields across liquid films

C. S. Perez-Martinez and S. Perkin, Soft Matter, 2019, 15, 4255 DOI: 10.1039/C9SM00143C

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