Table 1 shows summarized data from

Table 1 shows summarized data from sCA and cCA experiments, as well as a summary of the conditions necessary for the onset of condensation. Stable condensation was recorded as the lowest pressure where droplets were sustained through the quasi-static conditions in the chamber until the next incremental pressure increase. After the onset of stable condensation, a maximum average CA was eventually reached which was considered as the advancing cCA. Above this point, flooding was virtually unavoidable, but by lowering the ambient pressure evaporation could be used to minimize droplet coalescence. Receding cCAs were calculated as the minimum average droplet cCA as the pressure was lowered below the point of supersaturation. In analyzing the data to determine standard deviations, it was assumed that the droplets' angle cosines would follow Gaussian statistics. Re-converting from the linearized cosine form causes the distributions to appear skew normal.

A few particular points related to the wetting behavior shown in Fig. 4 are worthy of note. Most importantly, the cCAs were, in general, much lower than those measured by the sCA technique. Chemical and morphological inhomogeneities of NHSK films, combined with differences between the experimental details of these two techniques, serve to artificially increase the sCA while deflating the cCA. NHSK papers are statically hydrophobic but dynamically non-sliding. The hierarchical roughness is due to inter- and intra-NHSKs. The quasi-periodic arrangement of the kebab crystals with a 50 nm kebab spacing contributes to the nanoscale roughness; 2D random packing of these NHSKs leads to an inter-NHSK roughness that is ∼ a few hundred nanometers. In a sessile droplet measurement, the edges of a water droplet are pinned as a water droplet settles onto the surface, trapping air pockets underneath and making the measured sCA higher than they would be at equilibrium (Fig. 2e, inset). On the other hand, three effects are responsible for lowering the cCA: 1) Water adsorbs weakly to CNT sidewalls and to the creases in CNT bundles [38] and [39]. This suggests that as pressure within the SEM increases, a diffuse layer of water adsorbs on the CNT/NHSK paper surface even before actual water beads begin to form [40]. The “air pockets” formed in sCA are therefore absent in the cCA measurement. 2) The droplets formed in an ESEM are not at strict equilibrium. Ostwald ripening allows larger diameter drops to swell at the expense of smaller ones. Because the distribution includes an unweighted average of individual droplet cCAs, the final result can be lowered by the relatively large number of small droplets that are siphoned by the ripening process. 3) Droplet coalescence is also responsible for lowering the average cCA. In this case, because of the naturally low receding CA of NHSK paper [17], coalescing droplets will remain pinned at the outermost extremes of the contact circle boundaries. Thus, while the contact line might try to reorient to approach an equilibrium value, the pinning effect will dominate the behavior of droplets organizing at the surface [41] and [42].

Advancing cCAs follow a trend that mimics that of the sCA in that increasing the PE loading first increases, then decreases, following the nanoscale surface roughness [17]. Still, sCAs were found to be an average of 45° higher than cCAs. Nanocondensation droplet distributions were found to be exceptionally broad relative to the behavior of sessile drops. The reason for this is expected to be due to a combination of Ostwald ripening and droplet coalescence. A schematic representation of the expected mechanism of incipient droplet formation is shown in Fig. 5. The surface energy of the polymer single crystal fold surface is relatively low: for PE it is expected to be ∼104° [43]. Therefore, a cluster of water molecules is effectively confined to an intrakebab gallery. An incipient water droplet can only block a gas feed if it can form water wicks with droplets initiated at adjacent NHSK, so droplet confinement can effectively mitigate sample flooding if a liquid phase pressure gradient is imposed. Conversely, with SWCNT buckypaper, no polymer single crystals are present and so the relatively small pores that exist are quickly flooded. Condensation can occur in these films even below vapor phase saturation given a small change in temperature.