Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-23T06:40:04.551Z Has data issue: false hasContentIssue false

Nonlinear Electrohydrodynamic Stability of Two Superposed Walters B′ Viscoelastic Fluids in Relative Motion Through Porous Medium

Published online by Cambridge University Press:  23 May 2013

M. F. El-Sayed*
Affiliation:
Department of Mathematics, Faculty of Education, Ain Shams University, Heliopolis, Roxy, Cairo, Egypt
N. T. Eldabe
Affiliation:
Department of Mathematics, Faculty of Education, Ain Shams University, Heliopolis, Roxy, Cairo, Egypt
M. H. Haroun
Affiliation:
Department of Mathematics, Faculty of Education, Ain Shams University, Heliopolis, Roxy, Cairo, Egypt
D. M. Mostafa
Affiliation:
Department of Mathematics, Faculty of Education, Ain Shams University, Heliopolis, Roxy, Cairo, Egypt
Get access

Abstract

A nonlinear stability of two superposed semi-infinite Walters B′ viscoelastic dielectric fluids streaming through porous media in the presence of vertical electric fields in absence of surface charges at their interface is investigated in three dimensions. The method of multiple scales is used to obtain a Ginzburg-Landau equation with complex coefficients describing the behavior of the system. The stability of the system is discussed both analytically and numerically in linear and nonlinear cases, and the corresponding stability conditions are obtained. It is found, in the linear case, that the surface tension and medium permeability have stabilizing effects, and the fluid velocities, electric fields and kinematic viscoelastici-ties have destabilizing effects, while the porosity of porous medium and kinematic viscosities have dual role on the stability. In the nonlinear case, it is found that the fluid velocities, kinematic viscosities, kinematic viscoelasticities, surface tension and porosity of porous medium have stabilizing effects; while the electric fields and medium permeability have destabilizing effects.

Type
Research Article
Copyright
Copyright © The Society of Theoretical and Applied Mechanics, R.O.C. 2013 

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

REFERENCES

1.Chandrasekhar, S., Hydrodynamic and Hydreomag-netic Stability, Dover Publications, New York (1981).Google Scholar
2.Drazin, P. G., “Kelvin-Helmholtz Instability of Finite Amplitude,” Journal of Fluid Mechanics, 42, pp. 321335 (1970).CrossRefGoogle Scholar
3.Nayfeh, A. H. and Saric, W. S., “Nonlinear Waves in a Kelvin-Helmholtz Flow,” Journal of Fluid Mechanics, 55, pp. 311327 (1972).Google Scholar
4.Weissman, M. A., “Nonlinear Wave Packets in the Kelvin-Helmholtz instability,” Philosiphical Transactions of the Royal Society of London A, 290, pp. 639685 (1979).Google Scholar
5.Melcher, J. R. and Taylor, G. I., “Electrohydrody-namics: A Review of the Role of Interfacial Stresses,” Annual Review of Fluid Mechanics, 1, pp. 111146 (1969).Google Scholar
6.Taylor, G. I., “The Stability of a Horizontal Fluid Interface in a Vertical Electric Field,” Journal of Fluid Mechanics, 22, pp. 115 (1965).CrossRefGoogle Scholar
7.Melcher, J. R., Field Coupled Surface Waves: A Comparative Study of Surface-Coupled Electohy-drodynamic and Magnetohydrodynamic Systems, MIT Press, Cambridge (1963).Google Scholar
8.Jolly, D. C. and Melcher, J. R., “Electroconvective Instability in a Fluid Layer,” Procedings of the Royal Society of London A, 314, pp. 269283 (1970).Google Scholar
9.Melcher, J. R. and Smith, C. V., “Electrohydrody-namic Charge Relaxation and Interfacial Perpendicular-Field Instability,” Physics of Fluids, 12, pp. 778790 (1969).CrossRefGoogle Scholar
10.El-Sayed, M. F., “Nonlinear EHD Stability of the Travelling and Standing Waves of Two Superposed Dielectric Bounded Fluids in Relative Motion,” Physica A, 291, pp. 211228 (2001).Google Scholar
11.El-Sayed, M. F., “Electrohydrodynamic Wave-Packet Collapse and Soliton Instability for Dielectric Fluids in (2 + 1)-Dimensions,” European Physical Journal B, 37, pp. 241255 (2004).Google Scholar
12.El-Sayed, M. F., “Nonlinear Stability, Excitation and Soliton Solutions in Electrified Dispersive Systems,” Mathematics and Computers in Simulation, 79, pp. 242257 (2008).Google Scholar
13.El-Sayed, M. F., “Nonlinear Analysis and Solitary Waves for Two Super-Posed Streaming Electrified Fluids of Uniform Depths with Rigid BoundAries,” Archive of Applied Mechanics, 78, pp. 663685 (2008).CrossRefGoogle Scholar
14.El-Sayed, M. F., Elsabaa, F. M. F. and Amer, M. F. E., “On Nonlinear Electrohydrodynamic Instability of Liquid-Air Interface with the Liquid Having Finite Depth,” Journal of Natural Sciences and Mathematics, 5, pp. 5171 (2011).Google Scholar
15.Melcher, J. R., Continuum Electromechanics, MIT Press, Cambridge (1981).Google Scholar
16.Bobbio, S., Electrodynamics of Materials: Forces Stresses and Energies in Solids and Fluids, Academic Press, New York (2002).Google Scholar
17.Griffiths, G. J., Introduction to Electrohydrodynamics, 3rd Edition, Pearson Education, New Delhi, India (2006).Google Scholar
18.Abdella, A. and Rasmussen, H., “Electrohydrody-namic Instability of Two Superposed Fluids in Normal Electric Fields,” Journal Computational and Applied Mathematics, 78, pp. 3361 (1997).CrossRefGoogle Scholar
19.Mohamed, A. A., Elshehawey, E. F. and El-Dib, Y. O., “ElectrovisCoelastic Instability of a Kelvin-Fluid Layer Influenced by a Periodic ElecTric Force,” Journal of Colloid and Interface Science, 207, pp. 5469 (1998).Google Scholar
20.El-Sayed, M. F. and Callebaut, D. K., “EHD Envelope Solitons of Capillary-Gravity Waves in Fluids of Finite Depth,” Physica Scripta, 57, pp. 161170 (1998).Google Scholar
21.El-Sayed, M. F. and Callebaut, D. K., “Nonlinear EHD Stability of the Interfacial Waves of Two Superposed Dielectric Fluids,” Journal of Colloid and Interface Science, 200, pp. 203219 (1998).Google Scholar
22.El-Sayed, M. F. and Callebaut, D. K., “Nonlinear Electrohydrodynamic Stability of Two Superposed Bounded Fluids in the Presence of InterfaCial Surface Charges,” Zeitschrift Für Naturforschung A, 53, pp. 217232 (1998).Google Scholar
23.Vafai, K., Handbook of Porous Media, Marcel Dekker, New York (2000).Google Scholar
24.Pop, I. and Ingham, D. B., Convective Heat Transfer: Mathematical and Computational Modeling of Viscous Fluids and Porous Media, Pergamon Press, Oxford (2001).Google Scholar
25.Nield, D. A. and Bejan, A., Convection in Porous Media, 3rd Edition, Springer, Berlin (2006).Google Scholar
26.Bau, H. H., “Kelvin-Helmholtz Instability for Parallel Flow in Porous Media: A Linear Theory,” Physics of Fluids, 25, pp. 17191722 (1982).Google Scholar
27.Sharma, R. C. and Sunil, , Chand, S., “The Instability of Streaming Walters Viscoelastic Fluid B′ in Porous Medium,” Czechoslovak Journal of Physics, 49, pp. 189195 (1999).Google Scholar
28.Del Rio, J. A. and Whitaker, S., “Electrohydrodynamics in Porous Media,” Transport in Porous Media, 44, pp. 385405 (2001).Google Scholar
29.El-Sayed, M. F., “Electrohydrodynamic Instability of Two Superposed Viscous Streaming Fluids Through Porous Media,” Canadian Journal of Physics, 75, pp. 499508 (1997).CrossRefGoogle Scholar
30.El-Sayed, M. F., “Effect of Normal Electric Fields on Kelvin-Helmholtz Instability for Porous Media with Darcian and Forchheimer Flows,” Physica A, 255, pp. 114 (1998).Google Scholar
31.El-Sayed, M. F., “Instability of Two Streaming Conducting and Dielectric Bounded Fluids in Porous Medium Under Time-Varying Electric Field,” Archive of Applied Mechanics, 79, pp. 1939 (2009).Google Scholar
32.Mohamed, A. A., El-Dib, Y. O. and Mady, A. A., “Nonlinear Gravitational Stability of Streaming in an Electrified Viscous Flow Through Porous Media,” Chaos, Solitons and Fractals, 14, pp. 10271045 (2002).Google Scholar
33.Moatimid, G. M. and El-Dib, Y. O., “Nonlinear Kelvin-Helmholtz Instability of Oldroydian Viscoe-lastic Fluid in Porous Media,” Physica A, 333, pp. 4164 (2004).Google Scholar
34.El-Dib, Y. O. and Moatimid, G. M., “Nonlinear Stability of an Electrified Plane Interface in Porous Media,” Zeitschrift für Naturforschung A, 59, pp. 147162 (2004).Google Scholar
35.El-Sayed, M. F., Moatimid, G. M. and Metwaly, T. M. N., “Nonlinear Instability of Two Superposed Electrified Bounded Fluids Streaming Through Porous Medium in (2 + 1) Dimensions,” Journal of Porous Media, 12, pp. 11531179 (2009).Google Scholar
36.El-Sayed, M. F., Moatimid, G. M. and Metwaly, T. M. N., “Nonlinear Kelvin-Helmholtz Instability of Two Superposed Finite Fluids in Porous Medium Under Vertical Electric Fields,” Chemical Engineering Communications, 197, pp. 656683 (2010).Google Scholar
37.El-Sayed, M. F., Moatimid, G. M. and Metwaly, T. M. N., “Nonlinear Electrohydrodynamic Stability of Two Superposed Streaming Finite Dielectric Fluids in Porous Medium with Interfacial Surface Charges,” Transport in Porous Media, 86, pp. 559578 (2011).CrossRefGoogle Scholar
38.Landau, I. D. and Lifschitz, E. M., Electrodynamics of Continuous Media, Pergamon Press, New York (1960).Google Scholar
39.El-Sayed, M. F., Eldabe, N. T., Haroun, M. H. and Mostafa, D. M., “Nonlinear Kelvin-Helmholtz Instability of Rivlin-Ericksen Viscoelastic Electrified Fluid-Particle Mixtures Saturating Porous Medium,” European Physical Journal Plus, 127, article 29 (17 pages) (2012).Google Scholar
40.Nayfeh, A. H., Perturbation Methods, John Wiley and Sons, New York (1973).Google Scholar
41.El-Sayed, M. F., “Electrohydrodynamic Instability of Two Super-Posed Walters B′ Viscoelastic Fluids in Relative Motion Through Porous Medium,” Archive of Applied Mechanics, 71, pp. 717732 (2001).Google Scholar
42.Zahreddine, Z. and Elshehawey, E. F., “On the Stability of a System of Differential Equations with Complex Coefficients,” Indian Journal of Pure and Applied Mathematics, 19, pp. 963972 (1988).Google Scholar
43.Singla, R. K., Chhabra, R. K. and Trehan, S. K., “Effect of a Tangential Electric Field on the Second Harmonic Resonance in Kelvin-Helmholtz Flow,” Zeitschrift für Naturforschung A, 51, pp. 1016 (1996).CrossRefGoogle Scholar
44.Elshehawey, E. F., “Electrohydrodynamic Solitons in Kelvin-Helmholtz Flow: The Case of a Normal Field in the Absence of Surface Charges,” Quartely of Applied Mathematics, 44, pp. 481499 (1986).Google Scholar
45.Lange, C. G. and Newell, A. C., “A Stability Criterion for Envelope Equations,” SIAM Journal of Applied Mathematics, 27, pp. 441456 (1974).CrossRefGoogle Scholar
46.Matkowsky, B. J. and Volpert, V., “Stability of Plane Wave Solutions of Complex Ginzburg-Landau Equations,” Quartely of Applied Mathematics, 51, pp. 265281 (1993).Google Scholar
47.Pelap, F. B. and Faye, M. M., “Modulational Instability and Exact Solutions of the Modified Quintic Complex Ginzburg-Landau Equation,” Journal of Physics A: Mathematical and General, 37, pp. 17271736 (2004).Google Scholar