Droplet Mixing Using Electrically Tunable Superhydrophobic Nanostructured Surfaces

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Soft Matter Key Words

Nanostructures, DNA hybridization, superhydrophobic surface, droplet mixing


Recently there has been a lot of effort towards creating lab-on-a-chip devices. For a lab-on-a-chip device to be effective, it must be able to perform biological assays. Cost, portability, and time are all factors that come into play when designing a lab-on-a-chip device. Most of these devices deal with very small quantities of samples, on the order of a few microliters of fluid. Many biological assays, such as DNA hybridization, require effective mixing of the sample in order to speed up a process. In this vein, there has been a push towards effective mixing techniques for these devices. This papers discusses one method developed in the lab.


Aizenberg droplet.png

The group performs mixing by using electrowetting techniques. First, a superhydrophopic surface is fabricated by etching a lattice of nanoscale pillars into a silicon surface. A layer of thermal oxide was grown on top of these pillars, and then a layer of fluorocarbons was deposited on top of that. The fluorocarbon layer makes the surface extremely hydrophobic, yielding a contact angle as high as 150-160 degrees between a water droplet and the surface. A droplet of water placed on top of this surface sits on top of the pillars to minimize the contact area, as in the right hand side of the cartoon in figure a.