Inspired by the Salvinia effect, we report the fabrication and characterization of a novel "sticky" superhydrophobic surface sustaining a Cassie-Baxter wetting state for water droplets with high contact angles but strong solid-liquid retention. Unlike superhydrophobic surfaces mimicking the lotus or petal effect, whose hydrophobicity and droplet retention are typically regulated by hierarchical micro- and nanostructures made of a homogeneous material with the same surface energy, our superhydrophobic surface merely requires singular microstructures covered with a hydrophobic coating but creatively coupled with hydrophilic tips with different surface energy. Hydrophilic tips are selectively formed by meniscus-confined electrodeposition of a metal (e.g., nickel) layer on top of hydrophobic microstructures. During the electrodeposition process, the superhydrophobic surface retains its plastron so that the electrolyte cannot penetrate into the cavity of hydrophobic microstructures, consequently making the electrochemical reaction between solid and electrolyte occur only on the tip. In contrast to typical superhydrophobic surfaces where droplets are highly mobile, the "sticky" superhydrophobic surface allows a water droplet to have strong local pinning and solid-liquid retention on the hydrophilic tips, which is of great significance in many droplet behaviors such as evaporation.
Engineering surfaces
with excellent wicking properties is of critical
importance to a wide range of applications. Here, we report a facile
method to create superhydrophilic nanoporous micropillared surfaces
of silicon and their applicability to superwicking. Nanopores with
a good control of the pore depth are realized over the entire surface
of three-dimensional micropillar structures by electrochemical etching
in hydrofluoric acid. After rinsing in hydrogen peroxide, the nanoporous
micropillared surface shows superhydrophilicity with the superwicking
effect. The entire spreading process of a water droplet on the superhydrophilic
nanoporous micropillared surface is completed in less than 50 ms,
with an average velocity of 91.2 mm/s, which is significantly faster
than the other wicking surfaces reported. Owing to the presence of
nanopores on the micropillar array, the wicking dynamics is distinct
from the surfaces decorated only by micropillar arrays. The spreading
dynamics of a water droplet shows two distinct processes simultaneously,
including the capillary penetration between micropillars and the capillary
imbibition into the nanopore’s interior. The wicking dynamics
can be described by the two stages separated by the time when the
contact line starts to recede. The transition between the two wicking
regimes is due to the increasing effect of the imbibition of the bulk
droplet by the nanopores. While a similar transition of the wicking
dynamics is shown on the surfaces with different pore depths, the
nanopore structure with a greater depth causes a greater amount of
imbibition to slow down the spreading and promote superwicking.
In this paper, we report a simple fabrication process of whole Teflon superhydrophobic surfaces, featuring high-aspect-ratio (>20) nanowire structures, using a hot embossing process. An anodic aluminum oxide (AAO) membrane is used as the embossing mold for the fabrication of high-aspect-ratio nanowires directly on a Teflon substrate. First, high-aspect-ratio nanowire structures of Teflon are formed by pressing a fluorinated ethylene propylene (FEP) sheet onto a heated AAO membrane at 340 • C, which is above the melting point of FEP. Experimental results show that the heating time and aspect ratios of nanopores in the AAO mold are critical to the fidelity of the hot embossed nanowire structures. It has also been found that during the de-molding step, a large adhesive force between the AAO mold and the molded FEP greatly prolongs the length of nanowires. Contact angle measurements indicate that Teflon nanowires make the surface superhydrophobic. The reliability and robustness of superhydrophobicity is verified by a long-term (~6.5 h) underwater turbulent channel flow test. After the first step of hot-embossing the Teflon nanowires, microstructures are further superimposed by repeating the hot embossing process, but this time with microstructured silicon substrates as micromolds and at a temperature lower than the melting temperature of the FEP. The results indicate that the hot embossing process is also an effective way to fabricate hierarchical micro/nanostructures of whole Teflon, which can be useful for applications of Teflon material, such as superhydrophobic surfaces.
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