Conventional slippery surfaces show isotropic drop mobility in all directions, whereas anisotropic drop motion may often be required to guide drops in a particular direction. In most cases, topographically structured substrates are employed to provide...
Conventional slippery surfaces show isotropic drop mobility in all directions, whereas anisotropic drop motion may often be required to guide drops in a particular direction. In most cases, topographically structured substrates are employed to provide anisotropic drop motion, but this technique is neither efficient nor cost‐effective. Current findings elucidate a novel approach to control the drop motion by virtue of designing lubricated chemically heterogenous (LCHet) surfaces. Upon depositing aqueous drops on such surfaces, the underneath lubricating film dewets only from the hydrophilic regions but remains intact on the hydrophobic ones. This results in the formation of lubricated microchannels, which subsequently provides sticky and slippery regions for the drops. Fabricated surfaces show remarkable anisotropic drop sliding behavior, from uniform motion along parallel to stripes to stick–slip motion along perpendicular to them. Drop motion on such LCHet surfaces can be easily controlled and tuned in the desired direction by tuning the area fraction of hydrophobic region. Furthermore, a phase diagram is presented to summarize different dynamic situations exhibited by drops; sticking or moving in one or both directions. This approach can be easily adapted to different systems to produce multiranging applications from liquid micropatterning to anisotropic drop mobility.
Lubricated chemically heterogenous surfaces provide a simple approach to fabricate anisotropic slippery surfaces. Lubricating film dewets only from hydrophilic regions and remains intact on hydrophobic regions, forming anisotropic slippery tracks underneath water drops providing directional motion. By tuning the area fraction of the hydrophobic regions, different dynamic situations prevail from sticking to moving in one direction or both directions.