Abstract
Wetting phenomena in multi-phase systems govern the shape of the contact line which separates the different phases. For liquids in contact with solid surfaces wetting is typically described in terms of contact angle. While in macroscopic systems the contact angle can be determined experimentally, on the molecular scale contact angles are hardly accessible. Here we report the first direct experimental determination of contact angles as well as contact line curvature on a scale of the order of 1nm. For water nucleating heterogeneously on Ag nanoparticles we find contact angles around 15 degrees compared to 90 degrees for the corresponding macroscopically measured equilibrium angle. The obtained microscopic contact angles can be attributed to negative line tension in the order of −10−10 J/m that becomes increasingly dominant with increasing curvature of the contact line. These results enable a consistent theoretical description of heterogeneous nucleation and provide firm insight to the wetting of nanosized objects.
Highlights
Wetting phenomena in multi-phase systems govern the shape of the contact line which separates the different phases
Poor wetting properties are essential for any flying animal such as insects as they depend on proper wing run-off[1]
Contact angles in the macroscopic scale have been measured for various compounds using the telescope goniometer method[7,8], the Wilhelmy balance method[9,10], the capillary tube method[4] and a few other techniques
Summary
Wetting phenomena in multi-phase systems govern the shape of the contact line which separates the different phases. Interaction between cluster and particle surface leads to corresponding contact angle Θand angle Φ. Applying a macroscopic liquid drop concept, Fletcher[20] has used a contact angle to approximately describe the interaction between clusters and the underlying particle surface.
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