Frequency-based relationship of electrowetting and dielectrophoretic liquid microactuation

Authors
Jones, TBFowler, JDChang, YSKim, CJ
Issue Date
2003-09-02
Publisher
AMER CHEMICAL SOC
Citation
LANGMUIR, v.19, no.18, pp.7646 - 7651
Abstract
Electrowetting and dielectrophoretic actuation are potentially important microfluidic mechanisms for the transport, dispensing, and manipulation of liquid using simple electrode structures patterned on a substrate. These two mechanisms are, respectively, the low- and high-frequency limits of the electromechanical response of an aqueous liquid to an electric field. The Maxwell stress tensor and an RC circuit model are used to develop a simple predictive model for these electromechanics. The model is tested by measuring electric-field-induced pressure changes within an aqueous droplet trapped between two parallel, disk-shaped electrodes immersed in a bath of immiscible, insulating oil. The experiment is an adaptation of Quincke's original bubble method for measuring the dielectric constant of a liquid. For AC voltages lower than similar to100 V-rms, the pressure data largely conform to the square-law predictions of the model. At higher voltages, this square-law behavior is no longer evident, a result consistent with the well-known contact angle saturation effect. Pressure data obtained with DC electric fields are not consistent with either the lowest frequency data (10 Hz) or with the model.
Keywords
WATER; FILMS; ACTUATION; FIELDS; WATER; FILMS; ACTUATION; FIELDS; electrowetting
ISSN
0743-7463
URI
https://pubs.kist.re.kr/handle/201004/138238
DOI
10.1021/la0347511
Appears in Collections:
KIST Article > 2003
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