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Two-Phase Flow of Fluid-Particle Interaction over a Stretching Sheet in the Presence of Magnetic Field

  • J. Hasnain EMAIL logo , Z. Abbas and M. Sajid
Published/Copyright: July 16, 2019
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International Journal of Nonlinear Sciences and Numerical Simulation
From the journal International Journal of Nonlinear Sciences and Numerical Simulation Volume 20 Issue 6

Abstract

This article presents a theoretical study of magnetohydrodynamic boundary layer flow of a dusty viscoelastic fluid over a porous stretching sheet. The basic steady equations of the viscoelastic second grade fluid and dust phases are in the form of partial differential equations. A set of coupled nonlinear ordinary differential equations is obtained by using suitable similarity transformations. The approximate first order solutions of the resulting equations are obtained using the perturbation technique. The results are also verified with the well-known finite difference technique known as Keller box method. The physical insight of the involved parameters on the velocity of both fluid and dust phases and the skin-friction coefficient is shown through graphs and tables and discussed in detail. The study shows that an increased effective viscosity increases the velocity of both fluid and particle phase.

Keywords: Non-Newtonian fluid; dust particles; MHD; perturbation solution
PACS: 47.10.ad; 47.65.-d

Nomenclature

Vvelocity field for fluid phaseHdimensionless dust phase density
Vpvelocity field for dust phasevwsuction velocity
x,yspatial coordinatesKsecond grade parameter
u,vvelocity vector components for fluid in x and y directions, respectivelyMmagnetic parameter
up,vpvelocity vector components for dust in x and y directions, respectivelyRsuction parameter
Jcurrent densityGreek letters
Bmagnetic fieldα1,α2material constants
Nnumber density of dust particleτCauchy stress tensor
k=6πaμStokes constantμdynamic viscosity
aspherical radius of the dust particleρdensity of fluid
mmass of dust particleυkinematic viscosity
ppressureσelectrical conductivity
Iidentity tensorβfluid-particle interaction parameter
f,fdimensionless velocity components for fluid phaseαconstant
F,Gdimensionless velocity components for dust phaseηdimensionless quantity

Acknowledgements

We are thankful to the anonymous reviewer for his/her suggestions to improve the version of paper.

References

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Received: 2016-08-05
Accepted: 2019-06-25
Published Online: 2019-07-16
Published in Print: 2019-10-25

© 2019 Walter de Gruyter GmbH, Berlin/Boston

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https://doi.org/10.1515/ijnsns-2016-0110
Keywords for this article
Non-Newtonian fluid; dust particles; MHD; perturbation solution

Articles in the same Issue

  1. Frontmatter
  2. Research article
  3. Improved Results on Adaptive Control Approach for Projective Synchronization of Neural Networks with Time-Varying Delay
  4. A Method to Solve the Reaction-Diffusion-Chemotaxis System
  5. Two-Phase Flow of Fluid-Particle Interaction over a Stretching Sheet in the Presence of Magnetic Field
  6. An Algorithm for the Approximate Solution of the Fractional Riccati Differential Equation
  7. Additional Extension of the Mathematical Model for BCG Immunotherapy of Bladder Cancer and Its Validation by Auxiliary Tool
  8. Extended Transformed Rational Function Method to Nonlinear Evolution Equations
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