The combination of microscopic (atomic force microscopy and scanning electron microscopy) and goniometric (static and dynamic measurements) techniques, and surface characterization (surface free energy determination, critical surface tension, liquid entry pressure, hydraulic permeability) was implemented to discuss the influence of perfluoroalkylsilanes structure and grafting time on the physicochemistry of the created hydrophobic surfaces on the titania ceramic membranes of 5 kD and 300 kD. The impact of molecular structure of perfluoroalkylsilanes modifiers (possessing from 6 to 12 carbon atoms in the fluorinated part of the alkyl chain) and the time of the functionalization process in the range of 5 to 35 h was studied. Based on the scanning electron microscopy with energy-dispersive X-ray spectroscopy, it was found that the localization of grafting molecules depends on the membrane pore size (5 kD or 300 kD). In the case of 5 kD titania membranes, modifiers are attached mainly on the surface and only partially inside the membrane pores, whereas, for 300 kD membranes, the perfluoroalkylsilanes molecules are present within the whole porous structure of the membranes. The application of 4 various types of PFAS molecules enabled for interesting observations and remarks. It was explained how to obtain ceramic membrane surfaces with controlled material (contact angle, roughness, contact angle hysteresis) and separation properties. Highly hydrophobic surfaces with low values of contact angle hysteresis and low roughness were obtained. These surfaces possessed also low values of critical surface tension, which means that surfaces are highly resistant to wetting. This finding is crucial in membrane applicability in separation processes. The obtained and characterized hydrophobic membranes were subsequently applied in air-gap membrane distillation processes. All membranes were very efficient in MD processes, showing good transport and selective properties (∼99% of NaCl salt rejection). Depending on the membrane pore size and used modifiers, the permeate flux was in the range of 0.5-4.5 kg·m(-2)·h(-1) and 0.3-4.2 kg·m(-2)·h(-1) for 5 kD and 300 kD membranes, respectively.
Wetting of metal
surfaces plays an important role in fuel cells,
corrosion science, and heat-transfer devices. It has been recently
stipulated that Cu surface is hydrophobic. In order to address this
issue we use high purity (1 1 1) Cu prepared without oxygen, and resistant
to oxidation. Using the modern Fringe Projection Phase-Shifting method
of surface roughness determination, together with a new cell allowing
the vacuum and thermal desorption of samples, we define the relation
between the copper surface roughness and water contact angle (WCA).
Next by a simple extrapolation, we determine the WCA for the perfectly
smooth copper surface (WCA = 34°). Additionally, the kinetics
of airborne hydrocarbons adsorption on copper was measured. It is
shown for the first time that the presence of surface hydrocarbons
strongly affects not only WCA, but also water droplet evaporation
and the temperature of water droplet freezing. The different behavior
and features of the surfaces were observed once the atmosphere of
the experiment was changed from argon to air. The evaporation results
are well described by the theoretical framework proposed by Semenov,
and the freezing process by the dynamic growth angle model.
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