We manifest a significant influence of field direction and polarity on surface wetting, when the latter is tuned by application of an external electric field. Thermodynamics of field-induced filling of hydrocarbon-like nanopores with water is studied by open ensemble molecular simulation. Increased field strength consistently results in water-filling and electrostriction in hydrophobic nanopores. A threshold field commensurate with surface charge density of about one elementary charge per 10 nm2 suffices to render prototypical paraffin surfaces hydrophilic. When a field is applied in the direction perpendicular to the confining walls, the competition between orientational polarization and angle preferences of interfacial water molecules relative to the walls results in an asymmetric wettability of opposing surfaces (Janus interface). Reduction of surface free energy observed upon alignment of confinement walls with field direction suggests a novel mechanism whereby the applied electric field can operate selectively on water-filled nanotubes while empty ones remain unaffected.
Using molecular simulations of nanosized aqueous droplets on a model graphite surface, we demonstrate
remarkable sensitivity of water contact angles to the applied electric field polarity and direction relative to
the liquid/solid interface. The effect is explained by analyzing the influence of the field on interfacial hydrogen
bonding in the nanodrop, which in turn affects the interfacial tensions. The observed anisotropy in droplet
wetting is a new nanoscale phenomenon that has so far been elusive as, in current experimental setups, surface
molecules represent a very low fraction of the total number affected by the field. Our findings may have
important implications for the design of electrowetting techniques in fabrication and property tuning of
nanomaterials.
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