| Popis: |
We revisit the mesoscopic hydrodynamic description of the dynamics of sessile compound drops, i.e., of drops that consist of two immiscible nonvolatile partially wetting liquids and are situated on a smooth rigid solid substrate. We briefly discuss and complete existing models employing a gradient dynamics approach. Basing the underlying free energy on capillarity and wettability contributions for all relevant interfaces in their full-curvature variant we establish transparent consistency relations between macroscopic and mesoscopic parameters. In consequence, we obtain mesoscopic Neumann and Young laws that are also fully consistent with the macroscopic ones. In particular, we discuss the minimal requirements for the wetting energy that ensure the full spectrum of macroscopic parameters is addressed by the mesoscopic model. Having established the dynamic model in long-wave and full-curvature variants, the latter is employed to illustrate the usage of the mesoscopic model. As examples, we use the spreading of individual compound drops on one-dimensional horizontal substrates, sliding compound drops on one-dimensional inclined substrates, and the coarsening of drop ensembles on one- and two-dimensional horizontal substrates. In each case, the discussion emphasizes occurring qualitative changes in the drop configurations. |
