Peristaltic Flow of a Compressible Non-Newtonian Maxwellian Fluid Through Porous Medium in a Tube

Eldesoky, Islam M.; Mousa, Abd Allah A.

doi:10.1142/s1793524510000970

Cited by 30 publications

(42 citation statements)

References 30 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…From Figs. 8,9,11, it is seen that the volumetric flow rate decreases with increasing the height of the stenosis  , the magnetic parameter M and the Reynolds number Re while the volumetric flow rate increases with increasing the Darcian linear drag parameter  as shown in Fig. 10.…”

Section:  mentioning

confidence: 85%

Unsteady MHD Pulsatile Blood Flow through Porous Medium in a Stenotic Channel with Slip at the Permeable Walls Subjected to Time Dependent Velocity (Injection/Suction)

Eldesoky

2014

The International Conference on Mathematics and Engineering Phy

View full text Add to dashboard Cite

The flow through porous boundaries is of great importance both in technological as well as biophysical flows. The present paper is concerned with the study of unsteady pulsatile flow of blood through porous medium in a time dependent constricted porous channel subjected to time dependent suction/injection at the walls of the channel. The blood flow is subjected to a constant transverse magnetic field considering blood as an incompressible electrically conducting fluid. Due to the permeability of the arterial wall the no slip condition at the wall is no longer valid and one has to consider a slip condition at the channel wall. It was obliviously better and more realistic approach to obtain the flow behaviors. Perturbation analysis is used to solve the system of equations governing the flow. With a view to illustrating the applicability of the mathematical model developed here the analytic explicit expressions of axial velocity, volumetric flow rate and wall shear stress are obtained. The computed numerical results are presented graphically for different values of the physical parameters of interest to depict the variations in axial velocity, volumetric flow rate and wall shear stress.

show abstract

Section:  mentioning

confidence: 85%

Unsteady MHD Pulsatile Blood Flow through Porous Medium in a Stenotic Channel with Slip at the Permeable Walls Subjected to Time Dependent Velocity (Injection/Suction)

Eldesoky

2014

The International Conference on Mathematics and Engineering Phy

View full text Add to dashboard Cite

show abstract

“…In these investigations, many authors have used a no-slip boundary condition. Recently, some researchers have investigated boundary layer ow assuming a slip condition at the boundary [29][30][31][32][33][34][35].…”

Section: Introductionmentioning

confidence: 99%

Unsteady mixed convection flow through a permeable stretching flat surface with partial slip effects through MHD nanofluid using spectral relaxation method

2017

View full text Add to dashboard Cite

An unsteady, laminar, mixed convective stagnation point nano uid ow through a permeable stretching at surface using internal heat source or sink and partial slip is investigated. The e ects of thermophoresis and Brownian motion parameters are revised on the traditional model of nano uid for which nano uid particle volume fraction is passively controlled on the boundary. Spectral relaxation method is applied here to solve the nondimensional conservation equations. The results show the illustration of the impact of skin friction coe cient, different physical parameters, and the heat transfer rate. The nano uid motion is enhanced with increase in the value of the internal heat sink or source. On the other hand, the rate of heat transfer on the stretching sheet and the skin friction coe cient are reduced by an increase in internal heat generation. This study further shows that the velocity slip increases with decrease in the rate of heat transfer. The outcome results are benchmarked with previously published results.

show abstract

“…Since, the first investigation done by Latham (1966) a large amount of literature is available on peristaltic motion of Newtonian and non-Newtonian fluid with different flow geometries Akram, Nadeem, & Hanif, 2013;Ali, Hayat, & Asghar, 2009;Eldesoky, 2012Eldesoky, , 2013Eldesoky & Mousa, 2010;El-Shehawey, El-Dabe, & El-Desoky, 2006;Mittra & Prasad, 1973;Nadeem & Akram, 2010;Nadeem, Akram, & Akbar, 2013;Shapiro, Jaffrin, & Weinberg, 1969). Peristaltic mechanism is a fluid transport induced by a progressive wave of area contraction or expansion along the walls of a distensible tube containing fluid.…”

Section: Introductionmentioning

confidence: 99%

Peristaltic transport of a Maxwell fluid in a porous asymmetric channel through a porous medium

2014

View full text Add to dashboard Cite

show abstract

Peristaltic Flow of a Compressible Non-Newtonian Maxwellian Fluid Through Porous Medium in a Tube

Cited by 30 publications

References 30 publications

Unsteady MHD Pulsatile Blood Flow through Porous Medium in a Stenotic Channel with Slip at the Permeable Walls Subjected to Time Dependent Velocity (Injection/Suction)

Unsteady MHD Pulsatile Blood Flow through Porous Medium in a Stenotic Channel with Slip at the Permeable Walls Subjected to Time Dependent Velocity (Injection/Suction)

Unsteady mixed convection flow through a permeable stretching flat surface with partial slip effects through MHD nanofluid using spectral relaxation method

Peristaltic transport of a Maxwell fluid in a porous asymmetric channel through a porous medium

Contact Info

Product

Resources

About