Rayleigh-Taylor instability in thin liquid films subjected to harmonic vibration
The dynamics of the Rayleigh-Taylor instability of a two-dimensional thin liquid film placed on the underside of a planar substrate subjected to either normal or tangential harmonic forcing is investigated here in the framework of a set of long-wave evolution equations accounting for inertial effect...
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Veröffentlicht in: | Physics of fluids (1994) 2017-05, Vol.29 (5) |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | The dynamics of
the Rayleigh-Taylor
instability of a two-dimensional thin liquid film placed on the
underside of a planar substrate subjected to either normal or
tangential harmonic forcing is investigated here in the framework of a set of long-wave
evolution equations accounting for inertial effects derived earlier by Bestehorn, Han, and
Oron [“Nonlinear pattern formation in thin liquid films under external vibrations,” Phys. Rev. E
88, 023025 (2013)]. In the case of tangential vibration, the linear
stability analysis
of the time-periodic base state with a flat interface shows the existence of the domain of wavenumbers
where the film is
unstable. In the case of normal vibration, the linear stability analysis of the quiescent base
state reveals that the instability threshold of the system is depicted by a combination of
distinct thresholds separate for the Rayleigh-Taylor and Faraday instabilities. The
nonlinear
dynamics of the film
interface in the
case of the static substrate results in film rupture. However, in the presence of the substrate
vibration in the lateral direction, the film
interface
saturates in certain domains in the parameter space via the mechanism of advection induced
by forcing, so that the continuity of the film
interface is
preserved even in the domains of linear instability while undergoing the time-periodic harmonic
evolution. On the other hand, sufficiently strong forcing introduces a new inertial mode
of rupture. In the case of the normal vibration, the film evolution may exhibit
time-periodic, harmonic or subharmonic saturated waves apart of rupture. The enhancement
of the frequency or amplitude of the substrate forcing promotes the destabilization of the
system and a tendency to film rupture at the nonlinear stage of its evolution. A possibility of
saturation of the Rayleigh-Taylor
instability by either normal or unidirectional tangential forcing in
three dimensions is also demonstrated. |
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ISSN: | 1070-6631 1089-7666 |
DOI: | 10.1063/1.4984082 |