According to the engineers, when salt water flows over this specially patterned surface, it can produce at least 50 millivolts. The proof-of-concept work could lead to the development of new power sources for lab-on-a-chip platforms and other microfluidics devices. The researchers believe that it could someday be extended to energy harvesting methods in water desalination plants.
The main idea behind this work is to create electrical voltage by moving ions over a charged surface. The faster you can move these ions, the more voltage you can generate, explained Professor Prab Bandaru of the UC San Diego Jacobs School of Engineering.
Prof. Bandaru's team created a surface so hydrophobic that it enables water (and any ions it carries) to flow faster when passing over. The surface also holds a negative charge, so a rapid flow of positive ions in salt water with respect to this negatively charged surface results in an electrical potential difference, creating an electrical voltage.
"The reduced friction from this surface as well as the consequent electrical interactions helps to obtain significantly enhanced electrical voltage," explained Prof. Bandaru.
The surface was made by etching tiny ridges into a silicon substrate and then filling the ridges with oil (such as synthetic motor oil used for lubrication). In tests, dilute salt water was transported by syringe pump over the surface in a microfluidic channel, and then the voltage was measured across the ends of the channel.
There have been previous reports on super-hydrophobic, or so-called "lotus leaf" surfaces designed to speed up fluid flow at the surface. However, these surfaces have so far been patterned with tiny air pockets - and since air does not hold charge, the result is a smaller electric potential difference and thus, a smaller voltage.
By replacing air with a liquid like synthetic oil, which holds charge and won't mix with salt water, the engineers created a surface that produces at least 50 percent more electrical voltage than previous designs. According to Prof. Bandaru, higher voltages may also be obtained through faster liquid velocities and narrower and longer channels.
Moving forward, the team is working on creating channels with these patterned surfaces that can produce more electrical power.
