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Gravity-driven instability of a thin liquid film underneath a soft solid
Author(s) -
S. H. Lee,
Kara L. Maki,
Dan Flath,
Steven J. Weinstein,
C. Kealey,
Wenxuan Li,
Christopher J. Talbot,
Satish Kumar
Publication year - 2014
Publication title -
physical review e
Language(s) - English
Resource type - Journals
eISSN - 1550-2376
pISSN - 1539-3755
DOI - 10.1103/physreve.90.053009
Subject(s) - instability , eulerian path , mechanics , lubrication theory , lubrication , boundary value problem , surface tension , boundary (topology) , materials science , classical mechanics , representation (politics) , physics , mathematical analysis , thermodynamics , mathematics , lagrangian , political science , law , politics
The gravity-driven instability of a thin liquid film located underneath a soft solid material is considered. The equations and boundary conditions governing the solid deformation are systematically converted from a Lagrangian representation to an Eulerian representation, which is the natural framework for describing the liquid motion. This systematic conversion reveals that the continuity-of-velocity boundary condition at the liquid-solid interface is more complicated than has previously been assumed, even in the small-strain limit. We then make clear the conditions under which the commonly used simplified version of this boundary condition is valid. The small-strain approximation, lubrication theory, and linear stability analysis are applied to derive an expression for the growth rate of small-amplitude perturbations. Asymptotic analysis reveals that the coupling between the liquid and solid manifests itself as a lower effective liquid-air interfacial tension that leads to larger instability growth rates. Although this suggests that it is more difficult to maintain a stable liquid coating underneath a soft solid, the effect is expected to be weak for cases of practical interest.

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