Two-layer electrified pressure-driven flow in topographically structured channels
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Publication:5364545
DOI10.1017/jfm.2017.17zbMath1383.76033OpenAlexW2584260808MaRDI QIDQ5364545
Demetrios T. Papageorgiou, Elizaveta Dubrovina, Richard V. Craster
Publication date: 28 September 2017
Published in: Journal of Fluid Mechanics (Search for Journal in Brave)
Full work available at URL: http://hdl.handle.net/10044/1/49486
Uses Software
Cites Work
- Linear stability analysis of thin leaky dielectric films subjected to electric fields
- Nonlinear interfacial dynamics in stratified multilayer channel flows
- Suppressing van der Waals driven rupture through shear
- Linearly implicit methods for a semilinear parabolic system arising in two-phase flows
- Interfacial instability in electrified plane Couette flow
- Time-dependent free-surface thin film flows over topography
- Electrically induced pattern formation in thin leaky dielectric films
- Electrohydrodynamic instability of the interface between two fluids confined in a channel
- The effect of electric fields on the rupture of thin viscous films by van der Waals forces
- Linear stability of a two-fluid interface for electrohydrodynamic mixing in a channel
- Nonlinear rupture of free films
- AC electrohydrodynamic instabilities in thin liquid films
- Nonlinear Dynamics and Wall Touch-Up in Unstably Stratified Multilayer Flows in Horizontal Channels under the Action of Electric Fields
- Steady two-layer flow in a topographically patterned channel
- Quantifying the linear stability of a flowing electrified two-fluid layer in a channel for fast electric times for normal and parallel electric fields
- Nonlinear Dynamics of Electrified Thin Liquid Films
- Electrified viscous thin film flow over topography
- Shear-driven and channel flow of a liquid film over a corrugated or indented wall
- Wave evolution on electrified falling films
- Instability due to viscosity stratification
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