Difference between revisions of "Elektrowetting"
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== Surface Coating == | == Surface Coating == | ||
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== Electronic Controll == | == Electronic Controll == | ||
− | [[File:Electrowetting_electronics_ref1. | + | [[File:Electrowetting_electronics_ref1.png|x250px]]<br> |
− | [[File:Electrowetting_electronics_ref2. | + | [[File:Electrowetting_electronics_ref2.png|x250px]]<br> |
[1,2,3] | [1,2,3] |
Revision as of 13:49, 9 December 2014
Contents
Introduction
- Electrical charge of the surface changes the shape of water drops (before 1875)
- Electrowetting is the modification of the wetting properties of a surface by applying different electric fields (1981)
- "fluid transistor" for manipulating chemical and biological fluids (1980)
- Electrowetting on this dielectric-coated surface, EWOD (1993)
- Digital Microfluidic Circuits
What you need:
- insulating dielectric and hydrophobic layers
- immiscible fluids
- DC or RF power
- mass arrays of miniature interleaved electrodes (Indium tin oxide (ITO))
- digital control
- nano droplets
What you can do:
- move droplets in linear, circular and directed paths
- pump fluids
- mix fluids
- fill reservoirs
- move droplets over sensors or heaters
- control fluid flow electronically or optically
source: http://en.wikipedia.org/wiki/Electrowetting
DIY experiment
What you need:
- ribbon cable
- water, oil
- high voltage
What you can do:
Bio Device
Surface Coating
Electronic Controll
[1,2,3]
References
On chip Sample preparation utilising EWOD Concept
DNA Lab on a Chip
Sandia Digital Microfluidic Hub
The Electrowetting Display
1 Toward active-matrix lab-on-a-chip: programmable electrofluidic control enabled by arrayed oxide thin film transistors†
Joo Hyon Noh, a Jiyong Noh, a Eric Kreit, b Jason Heikenfeld b and Philip D. Rack
2 Electrowetting: from basics to applications, Frieder Mugele 1,3 and Jean-Christophe Baret
3 Programmable large area digital microfluidic array with integrated droplet sensing for bioassays, B. Hadwen, a G. R. Broder, b D. Morganti, b A. Jacobs, a C. Brown, a J. R. Hector, a Y. Kubota c and H. Morgan* b