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Ice Adhesion


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it is convenient to assume the water embryo nucleates on a surface with the shape of a spherical cap, as shown in Figure 2.3. By adopting the classical nucleation theory, the water nucleation barrier on a solid surface is expressed as,

      f is the geometry factor which depends on the wetting feature (i.e., water contact angle) and curvature of solid surface roughness. For an ideal planar surface with intrinsic contact angle θw of the water droplet (see Figure 2.3a), we obtain

      (2.12)c02_Inline_9_10.jpg

Schematic illustration of the volume and surface area of a spherical cap water nucleus on (a) a flat, partially wettable surface, (b) a convex, partially wettable surface, (c) a concave, partially wettable surface, and (d) a soft partially wettable surface.

      Figure 2.3 Schematic showing the volume and surface area of a spherical cap water nucleus on (a) a flat, partially wettable surface, (b) a convex, partially wettable surface, (c) a concave, partially wettable surface, and (d) a soft partially wettable surface.

      where m = cos θw = (σs,wσs,v)/σw,v is the wetting coefficient at the solid-water interface.

      For a convex surface with curvature Rc (e.g., nanobumps shown in Figure 2.3b), we obtain

      (2.13)c02_Inline_10_8.jpg

      where x = Rc/r* represents the size ratio of solid surface to the embryo, and g = (1 - 2mx + x2)1/2.

      For a concave surface with curvature Rc (e.g., nanopits shown in Figure 2.3c), we obtain

      where x = Rc/r* and g = (1 + 2mx + x2)1/2.

      When water vapor nucleates on solid elastic surfaces, however, the water nucleation barrier differs significantly from that of hard surfaces [93-95]. As shown in Figure 2.3d, for the droplet nucleating on a soft film, the surface tension of condensed water can pull the film surface upward along the periphery of the droplet. The Laplace pressure, meanwhile, compresses the soft film underneath the condensed droplet, forming a wetting ridge surrounding the droplet. Such deformation of soft surfaces apparently reduces the water nucleation barrier compared with the rigid surfaces. More investigations are still needed to quantitatively explore the effects of soft surface properties (e.g., viscosity) on the wetting feature of droplet embryos and associated water nucleation behavior.

      Based on the prediction of nucleation barrier ∆G*, the rate of heterogeneous water nucleation [m-2s-1] on a solid surface is given by,

      where c02_Inline_11_11.jpg is the concentration of single molecules adsorbed on the surface, c02_Inline_11_12.jpg is the molecular mass of water, hv is the latent heat of vaporization per molecule, υ is the vibration frequency of an adsorbed molecule normal to the surface (~1013 sec-1). A correction factor, Zeldovich factor Zs, denotes the probability that a nucleus of critical size will continue to grow instead of dissolving.

      (2.16)c02_Inline_12_5.jpg

      where p is the equilibrium vapor pressure at the water embryo surface, Dc is the diameter of concave surface structure (e.g., pore, cavity, etc.), nw is the number of water molecules per unit volume at the liquid phase. For a hydrophilic surface with θw < 90°, p will be smaller than the bulk saturation vapor pressure (psat,w), leading to water nucleation in cavity even in under-saturated conditions. A recent experimental study of capillary condensation revealed that at molecular scale, water with high negative (positive) curvature has surface tension higher (lower) than that of the bulk phase [96]. This implies that the nucleation of water molecules, or the critical water nucleus formation, is more prevalent than expected.

Schematic illustration of (a) an axisymmetric water nucleus on the microscale circular conical apex, flat, and microscale circular conical cavity. (b) Delta G, J0 and J as function of beta, and (c) water nucleation rate as a function of water contact angle alpha and structure parameter beta.

      Figure 2.4 (a) Schematic showing an axisymmetric water nucleus on the microscale circular conical apex (β < 180°), flat (β = 180°), and microscale circular conical cavity (β > 180°). (b) ΔG*, J0 and J as function of β (vapor pressure pv = 100 kPa, supersaturation S = 1.5, water contact angle θw = 90°). (c) Water nucleation rate as a function of water contact angle α and structure parameter β* (pv = 100 kPa, S = 1.5). Figure is reprinted with permission from [59].