Electro‐magneto‐hydrodynamic Eyring‐Powell fluid flow through micro‐parallel plates with heat transfer and non‐Darcian effects

Bhatti, Muhammad Mubashir; Doranehgard, Mohammad Hossein; Ellahi, R.

doi:10.1002/mma.8429

Cited by 7 publications

(3 citation statements)

References 53 publications

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“…In their research, Sharma et al [20] investigated the combined effect of thermophoresis and Brownian motion on magnetohydrodynamic mixed convective flow over an inclined stretching surface, considering the influence of thermal radiation and chemical reaction. Bhatti et al [21] investigated the electromagneto-hydrodynamic Eyring-Powell fluid flow through microparallel plates, considering heat transfer and non-Darcy effects. Khan et al [22] conducted an investigation on the flow of micropolar base nanofluid over a stretching sheet in the presence of thermal radiation and a magnetic dipole.…”

Section: Eejp 4 (2023)mentioning

confidence: 99%

Effect of Arrhenius Activation Energy in MHD Micropolar Nanofluid Flow Along a Porous Stretching Sheet with Viscous Dissipation and Heat Source

Borah,

Konch,

Chakraborty

2023

East Eur. J. Phys.

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A numerical study of the heat and mass transfer of a micropolar nanofluid flow over a stretching sheet embedded in a porous medium is carried out in this investigation. The main objective of this work is to investigate the influence of Arrhenius activation energy, heat source and viscous dissipation on the fluid velocity, microrotation, temperature, and concentration distribution. The equations governing the flow are transformed into ordinary differential equations using appropriate similarity transformations and solved numerically using bvp4c solver in MATLAB. Graphs are plotted to study the influences of important parameters such as magnetic parameter, porosity parameter, thermophoresis parameter, Brownian motion parameter, activation energy parameter and Lewis number on velocity, microrotation, temperature and concentration distribution. The graphical representation explores that the velocity of the liquid diminishes for increasing values of magnetic parameter, whereas the angular velocity increases with it. This study also reports that an enhancement of temperature and concentration distribution is observed for the higher values of activation energy parameter, whereas the Lewis number shows the opposite behavior. The effects of various pertinent parameters are exposed realistically on skin friction coefficient, Nusselt and Sherwood numbers via tables. A comparison with previous work is conducted, and the results show good agreement.

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Section: Eejp 4 (2023)mentioning

confidence: 99%

Effect of Arrhenius Activation Energy in MHD Micropolar Nanofluid Flow Along a Porous Stretching Sheet with Viscous Dissipation and Heat Source

Borah,

Konch,

Chakraborty

2023

East Eur. J. Phys.

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“…Magnetohydrodynamic has many usage in advanced manufacturing and other industries, which include films and drawing plastic wires, extruding polymers in the melting spinning processes, glass fiber production and crystal growth, manufacturing of foods and electronic chips, thermal energy storage, flow through filtering devices, fluid film in condensation processes, electrochemical processes and others. Several scholars have applied physical parameters to explore magnetohydrodynamic boundary layer flow across stretching and shrinking surfaces [3,7,8,21,26]. Additionally, since it has numerous uses in the medical and industrial sciences, nanotechnology has earned a great deal of interest from researchers.…”

Section: Introductionmentioning

confidence: 99%

MHD flow and heat transfer of micropolar nanofluid on a linearly stretching/shrinking porous surface

Kumar,

Shaikh,

Lanjwani

et al. 2023

VFAST trans. math.

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In this paper, there is considered incompressible steady two-dimensional laminar MHD boundary layer flow, heat and mass transfer characteristics of micropolar nanofluid across a linearly stretching/shrinking porous surface. The effects of the magnetic, thermal slip, mass slip and heat source sink parameters are also considered. By applyingn appropriate similarity variables, the system of governing partial differential equations associated to micropolar nanofluid flow is transformed into a system of non - linear ordinary differential equations. The resulting equations are numerically solved in the Maple software by using shooting technique. The impact of the different applied parameters on skin friction, couple stress, Nusselt and the Sherwood numbers along the related profiles are determined for both stretching and shrinking cases of the surfaces. It was observed that with an increase in suction and magnetic parameters, the fluid velocity decreased. An increment in the thermal slip, the fluid temperature decreased and nanoparticles concentration decreases as the mass slip parameter is enhanced. An increase in concentration decreases but temperature increases. While, concentration and temperature both increase due to increase in thermophoresis parameter, and concentration also increases by increase in rate of chemical reaction. Thus, suction at the boundary and magnetic parameter acted as flow controlling parameter. It is believed that this type of investigation is very much helpful for the manufacturing of complex fluids and also for cleaning oil from surfaces.

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“…Bhatti et al 23 studied natural convection non‐Newtonian electro‐MHD dissipative flow through a microchannel containing a non‐Darcy porous medium using the homotopy perturbation method. Bhatti et al 24 studied electro‐magneto‐hydrodynamic Eyring–Powell fluid flow through microparallel plates with heat transfer and non‐Darian effects. Bhatti et al 25 found the numerical solutions of hybrid nanofluid flow over a circular elastic surface with a non‐Darcy medium.…”

Section: Introductionmentioning

confidence: 99%

Characteristics of MHD nanofluid flow towards a vertical cone under convective cross‐diffusion effects through numerical solutions

Sathyanarayana

Goud

2022

Heat Trans

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In this study, the aim is to find the numerical solutions of steady, two‐dimensional, incompressible, viscous, electrically conducting magnetohydrodynamic (MHD) boundary‐layer nanofluid flow towards a vertical cone in the presence of thermal diffusion, diffusion thermo, thermophoresis, and Brownian motion effects subject to porous medium and convective boundary condition. For this investigation, the method of similarity transformations is used for the objective of converting nonlinear partial differential equations into the system of ordinary differential equations. Approximate solutions are obtained using a numerical method of the Runge–Kutta method with the shooting technique for the flow, heat, and mass transfer equations together with boundary conditions. For this flow, the impact of various engineering parameters on MHD, thermal, and solutal boundary layers is investigated and the results are displayed graphically. In addition, the numerical values of the local skin‐friction coefficient, rate of heat transfer, and rate of mass transfer coefficients are calculated, and the results are presented numerically. Finally, the comparison with previously published work is made and found in good agreement.

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Electro‐magneto‐hydrodynamic Eyring‐Powell fluid flow through micro‐parallel plates with heat transfer and non‐Darcian effects

Cited by 7 publications

References 53 publications

Effect of Arrhenius Activation Energy in MHD Micropolar Nanofluid Flow Along a Porous Stretching Sheet with Viscous Dissipation and Heat Source

Effect of Arrhenius Activation Energy in MHD Micropolar Nanofluid Flow Along a Porous Stretching Sheet with Viscous Dissipation and Heat Source

MHD flow and heat transfer of micropolar nanofluid on a linearly stretching/shrinking porous surface

Characteristics of MHD nanofluid flow towards a vertical cone under convective cross‐diffusion effects through numerical solutions

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