Hostname: page-component-78c5997874-m6dg7 Total loading time: 0 Render date: 2024-11-03T03:22:13.719Z Has data issue: false hasContentIssue false
  • English
  • Français

Viscosity effect on the longwave instability of a fluid interface subjected to horizontal vibrations

Published online by Cambridge University Press:  02 February 2017

D. V. Lyubimov ,
G. L. Khilko ,
A. O. Ivantsov  and
T. P. Lyubimova
D. V. Lyubimov
Affiliation:
Theoretical Physics Department, Perm State University, Perm 614990, Russia
G. L. Khilko
Affiliation:
Laboratory of Computational and Hydrodynamics, Institute of Continuous Media Mechanics UB RAS, Perm 614013, Russia
A. O. Ivantsov
Affiliation:
Theoretical Physics Department, Perm State University, Perm 614990, Russia Laboratory of Computational and Hydrodynamics, Institute of Continuous Media Mechanics UB RAS, Perm 614013, Russia
T. P. Lyubimova*
Affiliation:
Theoretical Physics Department, Perm State University, Perm 614990, Russia Laboratory of Computational and Hydrodynamics, Institute of Continuous Media Mechanics UB RAS, Perm 614013, Russia
*
Email address for correspondence: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

The effect of viscosity on the longwave Kelvin–Helmholtz instability of two immiscible incompressible fluids under horizontal vibrations is considered. The linear stability boundaries are found analytically using series expansion in terms of small wavenumber. The values of parameters, at which a transition from the longwave to finite-wavelength instability takes place, are determined. It has been shown that for high-frequency vibrations a viscous dissipation has just a weak destabilizing effect. At vibrations of moderate frequencies, destabilization is more significant, especially in the systems with large viscosity contrast. In contrast to that, at low frequencies the viscosity stabilizes the basic flow by suppressing the longwave perturbations.

JFM classification

Instability: Instability Multiphase and Particle-laden Flows: Multiphase flow Nonlinear Dynamical Systems: Pattern formation
Type
Papers
Information
Journal of Fluid Mechanics , Volume 814 , 10 March 2017 , pp. 24 - 41
Check for updates
Copyright
© 2017 Cambridge University Press 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bezdenezhnykh, N. A., Briskman, V. A., Lapin, A. Y., Lyubimov, D. V., Lyubimova, T. P., Tcherepanov, A. A. & Zakharov, I. V. 1991 The influence of high frequency tangential vibrations on the stability of the fluid interface in microgravity. Intl J. Microgravity Res. Appl. IV (2), 9697.Google Scholar
Bezdenezhnykh, N. A., Briskman, V. A., Lyubimov, D. V., Lyubimova, T. P., Zakharov, I. V. & Tcherepanov, A. A. 1992 The influence of high frequency tangential vibrations on the fluid interfaces in microgravity. In Microgravity Fluid Mechanics, pp. 137144. Springer.Google Scholar
Gandikota, G., Chatain, D., Amiroudine, S., Lyubimova, T. & Beysens, D. 2014 Frozen-wave instability in near-critical hydrogen subjected to horizontal vibration under various gravity fields. Phys. Rev. E 89, 012309.Google Scholar
Ivanova, A. A., Kozlov, V. G. & Evesque, P. 2001a Interface dynamics of immiscible fluids under horizontal vibration. Fluid Dyn. 36 (3), 362368.Google Scholar
Ivanova, A. A., Kozlov, V. G. & Tashkinov, S. I. 2001b Interface dynamics of immiscible fluids under circularly polarized vibration (experiment). Fluid Dyn. 36 (6), 871879.Google Scholar
Jalikop, S. V. & Juel, A. 2009 Steep capillary-gravity waves in oscillatory shear-driven flows. J. Fluid Mech. 640, 131150.Google Scholar
Kelly, R. E. 1965 The stability of an unsteady Kelvin–Helmholtz flow. Part 3. J. Fluid Mech. 22, 547560.Google Scholar
Khenner, M. V., Lyubimov, D. V., Belozerova, T. S. & Roux, B. 1999 Stability of plane-parallel oscillatory flow in a two-layer system. Eur. J. Mech. (B/Fluids) 18, 10851101.Google Scholar
Lyubimov, D. V. & Cherepanov, A. A. 1987 Development of a steady relief at the interface of fluids in a oscillatory field. Fluid Dyn. 21 (6), 849854.CrossRefGoogle Scholar
Lyubimov, D. V., Khenner, M. V. & Shotz, M. M. 1998 Stability of a fluid interface under tangential vibrations. Fluid Dyn. 33 (3), 318323.Google Scholar
Lyubimov, D. V. & Lyubimova, T. P. 1990 On a straight-through method of calculation for problems with deformable interface. Mod. Mech. 4(21) (1), 136140; (in Russian).Google Scholar
Lyubimov, D. V., Lyubimova, T. P. & Cherepanov, A. A. 2003 Dynamics of Interfaces in Vibration Fields. FizMatLit, (in Russian).Google Scholar
Shyh, C. K. & Munson, B. R. 1986 Intrefacial instability of an oscillating shear layer. Trans. ASME J. Fluids Engng 108, 8992.Google Scholar
Talib, E., Jalikop, S. V. & Juel, A. 2007 The influence of viscosity on the frozen wave instability: theory and experiment. J. Fluid Mech. 584, 4568.CrossRefGoogle Scholar
Talib, E. & Juel, A. 2007 Instability of a viscous interface under horizontal oscillation. Phys. Fluids 19, 092102.CrossRefGoogle Scholar
Wolf, G. H. 1969 The dynamic stabilization of Rayleigh–Taylor instability and corresponding dynamic equilibrium. Z. Phys. B 227, 291300.Google Scholar
Wunenburger, R., Evesque, P., Chabot, C., Garrabos, Y., Fauve, S. & Beysens, D. 1999 Frozen wave instability by high frequency horizontal vibrations on a CO2 liquid–gas interface near the critical point. Phys. Rev. E 59, 54405445.Google Scholar
Yoshikawa, H. N. & Wesfreid, J. E. 2011 Oscillatory Kelvin–Hemlholtz instability. Part 1. A viscous theory. J. Fluid Mech. 675, 223248.Google Scholar