We present here a detailed study
of the wettability of surfaces
nanostructured with amorphous and crystalline nanoparticles (NPs)
derived from the phase-change material Ge2Sb2Te5 (GST). Particular attention was devoted to the effect
of airborne surface hydrocarbons on surface wetting. Our analysis
illustrates that a reversible hydrophilic–hydrophobic wettability
switch is revealed by combined ultraviolet-ozone (UV-O3) treatments and exposure to hydrocarbon atmospheres. Indeed, the
as-prepared surfaces exhibited a hydrophilic state after thermal annealing
or UV-O3 treatment which can partially remove hydrocarbon
contaminants, while a hydrophobic state was realized after exposure
to hydrocarbon atmosphere. Using high-angle annular dark-field scanning
transmission electron microscopy for the specially designed GST NP
decorated graphene substrates, a network of hydrocarbon connecting
GST NPs was observed. Our findings indicate that airborne hydrocarbons
can significantly enhance the hydrophobicity of nanostructured surfaces.
Finally, the experiments reveal that previously defined hydrophilic
materials can be used for the design of hydrophobic surfaces even
if the meniscus is highly adhered to a solid surface, which is in
agreement with our qualitative model involving the contribution of
the nanomeniscus formed between the substrate and a decorating NP.
The wetting state of surfaces can be rendered to a highly hydrophobic state by the deposition of hydrophilic gas phase synthesized Ag nanoparticles (NPs). The aging of Ag NPs leads to an increase in their size, which is also associated with the presence of Ag adatoms on the surface between the NPs that have a strong effect on the wetting processes. Furthermore, surface airborne hydrocarbons were removed by UV-ozone treatment, providing deeper insight into the apparent mobility of the NPs on different surfaces and their subsequent ripening and aging. In addition, the UV-ozone treatment revealed the presence of adatoms during the magnetron sputtering process. This surface treatment lowers the initial contact angle of the substrates and facilitates the mobility of Ag NPs and adatoms on the surface of substrates. Adatoms co-deposited on clean high surface energy substrates will nucleate on Ag NPs that will remain closely spherical and preserve the pinning effect due to the water nanomeniscus. If the adatoms are co-deposited on a UV-ozone cleaned low surface energy substrate, their mobility is restricted, and they will nucleate in two-dimensional islands and/or nanoclusters on the surface instead of connecting to existing Ag NPs. This growth results in a rough surface without overhangs, where the wetting state is reversed from hydrophobic to hydrophilic. Finally, different material surfaces of transmission electron microscopy grids revealed strong differences in the sticking coefficient for the Ag NPs, suggesting another factor that can strongly affect their wetting properties.
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