Abstract
We present a rapid, simple, and scalable approach to achieve superhydrophobic (SH) substrates directly in commodity shrink wrap film utilizing Argon (Ar) plasma. Ar plasma treatment creates a stiff skin layer on the surface of the shrink film. When the film shrinks, the mismatch in stiffness between the stiff skin layer and bulk shrink film causes the formation of multiscale hierarchical wrinkles with nano-textured features. Scanning electron microscopy (SEM) images confirm the presence of these biomimetic structures. Contact angle (CA) and contact angle hysteresis (CAH) measurements, respectively, defined as values greater than 150° and less than 10°, verified the SH nature of the substrates. Furthermore, we demonstrate the ability to reliably pattern hydrophilic regions onto the SH substrates, allowing precise capture and detection of proteins in urine. Finally, we achieved self-driven microfluidics via patterning contrasting superhydrophilic microchannels on the SH Ar substrates to induce flow for biosensing.
Highlights
IntroductionThe lotus leaf consists of micro and nano-structured features that allows for self-cleaning properties, while the Namib Desert beetle has alternating SH and hydrophilic regions to optimize water collection under extreme desert conditions [1,2,3]
Superhydrophobic (SH) surfaces are found widely throughout nature with a variety of purposes.For example, the lotus leaf consists of micro and nano-structured features that allows for self-cleaning properties, while the Namib Desert beetle has alternating SH and hydrophilic regions to optimize water collection under extreme desert conditions [1,2,3]
Superhydrophobicity is characterized as having a water contact angle (CA) greater than
Summary
The lotus leaf consists of micro and nano-structured features that allows for self-cleaning properties, while the Namib Desert beetle has alternating SH and hydrophilic regions to optimize water collection under extreme desert conditions [1,2,3]. Inspired by these naturally occurring SH surfaces, both industrial and academic sectors have significant interest in mimicking and recreating the unique water-repellant property of SH features for numerous commercial and biomedical applications [4]. Superhydrophobicity is characterized as having a water contact angle (CA) greater than
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