Hmmm - XDSL. at breakout resistance. O
Post# of 63831
Posted On: 04/06/2013 3:13:17 PM
Hmmm - XDSL. at breakout resistance.
Our technology exploits the phenomenon of electrowetting - the ability to electronically manipulate the way liquids behave when in contact with a solid or porous surface. Water will bead up on a surface that is superhydrophobic*, but can be made to move or spread out by electrowetting. The same is true for an organic liquid if the surface is superlyophobic.
It is noteworthy that research groups across the country through out several esteemed universities including MIT, Rutgers and the University of Wisconsin are now publicizing their work on electrowetting and superhydrophobicity and superlyophobicity to create so-called “smart” structures on metal, ceramic or polymer surfaces that resist getting dirty, fogging up, or forming ice. They also can be used for displays, lenses and other applications.
By exploiting the same phenomena in our Smart NanoBattery by manipulating the liquid electrolyte via a proprietary silicon structure - a porous membrane - and coupled with unique battery architecture shown above.
Our technology exploits the phenomenon of electrowetting - the ability to electronically manipulate the way liquids behave when in contact with a solid or porous surface. Water will bead up on a surface that is superhydrophobic*, but can be made to move or spread out by electrowetting. The same is true for an organic liquid if the surface is superlyophobic.
It is noteworthy that research groups across the country through out several esteemed universities including MIT, Rutgers and the University of Wisconsin are now publicizing their work on electrowetting and superhydrophobicity and superlyophobicity to create so-called “smart” structures on metal, ceramic or polymer surfaces that resist getting dirty, fogging up, or forming ice. They also can be used for displays, lenses and other applications.
By exploiting the same phenomena in our Smart NanoBattery by manipulating the liquid electrolyte via a proprietary silicon structure - a porous membrane - and coupled with unique battery architecture shown above.
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