In this paper, we study in detail the electrowetting behavior of a liquid-metal droplet (mercury) on top of a dielectric insulating layer experimentally. 74° of the contact angle change (from 141° to 67°) is achieved by applying a voltage of 180V to a mercury droplet on a Parylene surface. By using a very thin Teflon AF coating, low contact angle hysteresis (2°) and highly reversible electro-wetting are reported. The dynamic responses of the droplet to a voltage stair and a voltage pulse are video-captured and analyzed by using a high-speed camera. The electrowetting has very fast rise/fall time, which is suitable for application in MEMS devices. By using a high-k material as the insulating layer along with a thin Teflon AF coating, a very large contact angle change of 40° (from 150° to 110°) is achieved with only 30V. Saturation of the electrowetting behavior is also observed and discussed. Applications of the electrowetting effect of a liquid-metal droplet in MEMS devices are discussed.

Volume Subject Area:
Fluids Engineering
Keywords:
Electrowetting, Contact angle, Hysteresis
Topics:
Drops, Liquid metals, Coating processes, Coatings, Microelectromechanical systems, Dynamic response, Stairs, Wetting
1.
Berge
B.
C. R. Acad. Sci. Ser. II
1993
,
317
,
157
157
.
2.
Prins
M. W. J.
,
Welters
W. J. J.
, and
Weekamp
J. W.
2001
. “
Fluid Control in Multichannel Structures by Electrocapillary Pressure
.”,
Science
291
,
277
277
3.
Z. L. Wan, J. MEMS. Vol 13, No. 4, 2004. “Electrocapillary piston motion and a prototype of phasemanipulating micromirror.”
4.
Bergea
B.
and
Peseux
J.
 (
2000
) “
Variable focal lens controlled by an external voltage An application of electrowetting
.”,
Eur. Phys. J. E
3
,
159
163
5.
Hayes
R. A.
and
Feenstra
B. J.
 (
2003
) “
Video speed electronic paper based on electrowetting
.”,
Nature
425
,
383
385
6.
Lee, J., Kim, C. J., 1998, Proc. IEEE MEMS ’98, Heidelberg, Germany, pp. 538–543. “Liquid Micromotor Driven by Continuous Electrowetting.”
7.
Hongjun Zeng, Alan D. Feinerman, Zhiliang Wan, and Pancham R. Patel, J. MEMS, VOL. 14, NO. 2, 2005. “Piston-Motion Micromirror Based on Electrowetting of Liquid Metals.”
8.
Darhuber
Anton A.
,
Valentino
Joseph P.
,
Davis
Jeffrey M.
, and
Troiana
Sandra M.
,
2003
. “
Microfluidic actuation by modulation of surface stresses.
APPLIED PHYSICS LETTERS
82
(
4
) p.
27
27
9.
Pollack
M. G.
;
Fair
R. B.
;
Shenderov
A. D.
Appl. Phys. Lett.
2000
,
77
,
1725
1725
.
10.
Quillieta
Catherine
,
Bergeb
Bruno
Electrowetting a recent outbreak
.”,
Current Opinion in Colloid & Interface Science
6
2001
34
39
11.
Peykov
V.
,
Quinm
A.
,
Ralston
J.
 (
2000
) “
Electrowetting a model for contact-angle saturation
.”,
Colloid Polym Sci
278
789
793
12.
Vallet
M.
,
Vallade
M.
, and
Bergea
B.
 (
1999
) “
Limiting phenomena for the spreading of water on Polymer films by electrowetting
.”
Eur. Phys. J. B
11
,
583
591
13.
Decamps
C.
and
De Coninck
J.
Dynamics of Spontaneous Spreading under Electrowetting Conditions
.”
Langmuir
2000,
16
,
10150
10153
14.
Adachi
K.
and
Takaki
R.
,
1984
. “
Vibration of a flattened drop I. Observation
.”,
J. Phys. Soc. Japan
, vol.
53
, no.
12
, pp.
4184
4191
15.
Klingner
Anke
,
Herminghaus
Stephan
, and
Mugelea
Frieder
2003
Self-excited oscillatory dynamics of capillary bridges in electric fields
.”
APPLIED PHYSICS LETTERS
82
(
23
) p.
9
9
This content is only available via PDF.
Copyright © 2005
 by ASME
You do not currently have access to this content.