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Interfacial dynamics of a confined liquid–vapour bilayer undergoing evaporation

Published online by Cambridge University Press:  15 October 2018

Dipin S. Pillai Open the ORCID record for Dipin S. Pillai [Opens in a new window]  and
R. Narayanan
Dipin S. Pillai*
Affiliation:
Department of Chemical Engineering, University of Florida, Gainesville, FL 32611, USA
R. Narayanan
Affiliation:
Department of Chemical Engineering, University of Florida, Gainesville, FL 32611, USA
*
Email address for correspondence: dipinsp@ufl.edu
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Abstract

The dynamics of an interface between a thin liquid–vapour bilayer undergoing evaporation is studied. Both phases are considered to be hydrodynamically and thermally active, with momentum and thermal inertia taken into account. A reduced-order model based on the weighted-residual integral boundary layer method is used to investigate the dynamical behaviour for two cases, viz., phase change in the absence of gravity and then phase change in the presence of gravity. In the first case, it is shown that evaporative instability may cause rupture of either liquid or vapour layer depending on system parameters. Close to interfacial rupture, the disjoining pressure due to intermolecular forces results in the formation of drops (bubbles) separated by a thin film for low liquid (vapour) hold-up. Momentum inertia is shown to have a stabilizing effect, while thermal inertia has a destabilizing effect. In the second case, evaporative suppression of Rayleigh–Taylor (R–T) instability shows emergence of up to two neutral wavenumbers. Weak nonlinear analysis of these neutral wavenumbers suggests that the instability may be either supercritical or subcritical depending on the rate of evaporation. At high rates of evaporation, both neutral wavenumbers are supercritical and computations on the interface evolution lead to nonlinear saturated steady states. Momentum inertia slows down the rate of interface deformation and results in an oscillatory approach to saturation. Thermal inertia results in larger interface deformation and the saturated steady state is shifted closer to the wall. At very low evaporation rates, only one neutral wavenumber of subcritical nature exists. The nonlinear evolution of the interface in this case is then similar to pure R–T instability, exhibiting spontaneous lateral sliding as it approaches the wall.

JFM classification

Phase change: Condensation/evaporation Interfacial Flows (free surface): Interfacial Flows (free surface) Interfacial Flows (free surface): Thin films
Type
JFM Papers
Information
Journal of Fluid Mechanics , Volume 857 , 25 December 2018 , pp. 1 - 37
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Copyright
© 2018 Cambridge University Press 

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Pillai and Narayanan supplementary movie 1

Spatio-temporal evolution of the interface profile for evaporative instability when heated from the liquid side showing vapour rupture

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Video 822.1 KB
Supplementary material: File

Pillai and Narayanan supplementary material

Supplementary material

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File 15.8 KB

Pillai and Narayanan supplementary movie 2

Spatio-temporal evolution of the interface profile for evaporative instability when heated from the liquid side showing liquid rupture

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Video 909.9 KB

Pillai and Narayanan supplementary movie 3

Spatio-temporal evolution of the interface profile for evaporative instability when heated from the liquid side showing liquid rupture

Download Pillai and Narayanan supplementary movie 3(Video)
Video 1.1 MB

Pillai and Narayanan supplementary movie 4

Nonlinear saturation of the interface profile for a Rayleigh-Taylor unstable system heated from the vapour side; H=0.3, E=6.1×10-5, k=0.2

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Video 770.1 KB

Pillai and Narayanan supplementary movie 5

Nonlinear saturation of the interface profile for a Rayleigh-Taylor unstable system heated from the vapour side; H=0.3, E=1.22×10-5, k=0.2.

Download Pillai and Narayanan supplementary movie 5(Video)
Video 748.7 KB

Pillai and Narayanan supplementary movie 6

Velocity profile in each phase for the R-T unstable configuration, exhibiting a flow reversal in the liquid phase as the interface attains its steady state

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Video 1.3 MB

Pillai and Narayanan supplementary movie 7

Steady interface profile close to the left neutral wavenumber (k = 1.01 kcL); kcL = 0.081

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Video 1.8 MB

Pillai and Narayanan supplementary movie 8

Oscillatory approach to saturation of the interface in the presence of momentum inertia in evaporative suppresion of R-T instability

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Video 689.3 KB
Supplementary material: File

Pillai and Narayanan supplementary material

Supplementary data

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