Comment on "Large slip of aqueous liquid flow over a nanoengineered superhydrophobic surface".

Large slip of aqueous liquid flow over a nanoengineered superhydrophobic surface

Electro-osmotic flow over a charged superhydrophobic surface.

Bubbles can be trapped inside textured structures such as grooves, forming a superhydrophobic surface. A superhydrophobic surface has a large effective hydrodynamic slip length compared to a smooth hydrophobic surface and holds the promise of enhancing electrokinetic flows that find many interesting applications in microfluidics. However, recent theoretical studies suggested that electro-osmoti...

Toward generating low-friction nanoengineered surfaces with liquid-vapor interfaces.

Using molecular dynamics (MD), we investigate the importance of liquid-vapor interface topography in designing low-friction nanoengineered superhydrophobic surfaces. Shear flow is simulated on patterned surfaces. The relationship between the effective slip length and bubble meniscus curvature is attained by generating entrapped bubbles with large protrusion angles on patterned surfaces with nan...

Effective slip and friction reduction in nanograted superhydrophobic microchannels

Enabled by a technology to fabricate well-defined nanogrates over a large area 2 2 cm2 , we report the effect of such a surface, in both hydrophilic and hydrophobic conditions, on liquid slip and the corresponding friction reduction in microchannels. The grates are designed to be dense 230 nm pitch but deep 500 nm in order to sustain a large amount of air in the troughs when the grates are hydr...

Slippage of water past superhydrophobic carbon nanotube forests in microchannels.

We present in this Letter an experimental characterization of liquid flow slippage over superhydrophobic surfaces made of carbon nanotube forests, incorporated in microchannels. We make use of a particle image velocimetry technique to achieve the submicrometric resolution on the flow profile necessary for accurate measurement of the surface hydrodynamic properties. We demonstrate boundary slipp...