Analytical Investigation of Magnetohydrodynamic Non-Newtonian Type Casson Nanofluid Flow past a Porous Channel with Periodic Body Acceleration

The consequence of periodic body acceleration and thermal radiation in the pulsating flow of MHD Casson nanofluid through a porous channel is addressed. A flow of the nanofluid injected through the lower plate is considered while sucked out through the upper plate with a similar velocity. The thermal radiation term is incorporated in the heat transfer equation. The governing equations corresponding to velocity and temperature are converted from partial differential equations to a system of ordinary differential equations by employing similarity variables. The perturbation technique is applied to solve the governing flow equations. The impact of diverse parameters on flow features is graphically analyzed. The result reveals that adding the nanoparticle has enhanced the velocity profile of the base fluid. Moreover, an increase in the periodic body acceleration results in enlarging velocity and temperature.

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MHD Pulsating Flow of Casson Nanofluid in a Vertical Porous Space with Thermal Radiation and Joule Heating

Journal of Mechanics ◽

10.1017/jmech.2020.5 ◽

2020 ◽

Vol 36 (4) ◽

pp. 535-549

Author(s):

Challa Kalyan Kumar ◽

Suripeddi Srinivas ◽

Anala Subramanyam Reddy

Keyword(s):

Brownian Motion ◽

Differential Equations ◽

Thermal Radiation ◽

Motion Parameter ◽

Porous Space ◽

Perturbation Scheme ◽

Casson Nanofluid ◽

Nanoparticles Concentration ◽

The Impact ◽

Brownian Motion Parameter

ABSTRACTIn this investigation, the magnetohydrodynamic pulsatile flow of Casson nanofluid through a vertical channel embedded in porous medium with thermal radiation and heat generation/absorption has been analyzed using Buongiorno model. The influence of viscous and Joules dissipations are taken into account. The governing coupled partial differential equations are reduced to ordinary differential equations using perturbation scheme and then solved numerically by using Runge-Kutta fourth order technique along with shooting method. The impact of various emerging parameters on velocity, temperature, nanoparticles concentration, Nusselt number and Sherwood number distributions are analyzed in detail. Analysis indicates that the temperature distribution increases for a given increase in Brownian motion parameter and thermophoresis parameter, while it decreases with an increase in Hartmann number. Further, the nanoparticles concentration distribution decreases with an increase in the chemical reaction parameter and the Lewis number, while it increases for a given increase in the Brownian motion parameter.

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Influence of nonlinear thermal radiation on rotating flow of Casson nanofluid

Nonlinear Engineering ◽

10.1515/nleng-2017-0041 ◽

2018 ◽

Vol 7 (2) ◽

pp. 91-101 ◽

Cited By ~ 5

Author(s):

M. Archana ◽

B. J. Gireesha ◽

B. C. Prasannakumara ◽

R.S.R. Gorla

Keyword(s):

Differential Equations ◽

Thermal Radiation ◽

Nonlinear Thermal Radiation ◽

Shooting Technique ◽

Casson Nanofluid ◽

Similarity Transformations ◽

Heating Effects ◽

Temperature Component ◽

Fifth Order ◽

The Impact

Abstract The heat and mass transfer of rotating Casson nanofluid flow is incorporated in the present study. Influence of magnetic field, nonlinear thermal radiation, viscous dissipation and Joule heating effects are taken into the account. A set of nonlinear ordinary differential equations are obtained from the governing partial differential equations with the aid of suitable similarity transformations. The resultant equations are solved for the numerical solution using Runge-Kutta-Fehlberg fourth-fifth order method along with shooting technique. The impact of several existing physical parameter on velocity, temperature and nanofluid concentration profiles are analyzed through graphs and tables in detail. It is found that, velocity component decreases and temperature component increases for rotating parameter.

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Oscillatory Flow MHD of Jeffrey Fluid with Temperature-Dependent Viscosity (TDV) in a Saturated Porous Channel

Iraqi Journal of Science ◽

10.24996/ijs.2021.si.2.3 ◽

2021 ◽

pp. 27-34

Author(s):

Wissam Sadiq Khudair ◽

Hasan Hadi Dwail ◽

Hayder Kadim Mohammed

Keyword(s):

Magnetic Parameter ◽

Perturbation Technique ◽

Porous Channel ◽

Jeffrey Fluid ◽

Physical Parameters ◽

Temperature Dependent ◽

Temperature Dependent Viscosity ◽

Flow Equations ◽

Dependent Viscosity ◽

The Impact

In this research, we studied the impact of Magnetohydrodynamic (MHD) on Jeffrey fluid with porous channel saturated with temperature-dependent viscosity (TDV). It is obtained on the movement of fluid flow equations by using the method of perturbation technique in terms of number Weissenberg ( ) to get clear formulas for the field of velocity. All the solutions of physical parameters of the Reynolds number , Magnetic parameter , Darcy parameter , Peclet number and are discussed under the different values, as shown in the plots.

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EFFECT OF HEAT AND MASS TRANSFER AND THERMAL RADIATION ON A STEADY MHD CONVECTIVE FLOW WITH VISCOUS DISSIPATION AND SUCTION/INJECTION

Latin American Applied Research - An international journal ◽

10.52292/j.laar.2022.754 ◽

2022 ◽

Vol 52 (1) ◽

pp. 35-41

Author(s):

Silpisikha Goswami ◽

Kamalesh Kumar Pandit ◽

Dipak Sarma

Keyword(s):

Nusselt Number ◽

Thermal Radiation ◽

Temperature Profile ◽

Skin Friction ◽

Viscous Dissipation ◽

Sherwood Number ◽

Fluid Velocity ◽

Physical Parameters ◽

Flow Equations ◽

The Impact

Our motive is to examine the impact of thermal radiation and suction or injection with viscous dissipation on an MHD boundary layer flow past a vertical porous stretched sheet immersed in a porous medium. The set of the flow equations is converted into a set of non-linear ordinary differential equations by using similarity transformation. We use Runge Kutta method and shooting technique in MATLAB Package to solve the set of equations. The impact of non-dimensional physical parameters on flow profiles is analysed and depicted in graphs. We observe the influence of non-dimensional physical quantities on the Nusselt number, the Sherwood number, and skin friction and presented in tables. A comparison of the obtained numerical results with existing results in a limiting sense is also presented. We enhance radiation to observe the deceleration of fluid velocity and temperature profile for both suction and injection. While enhancing porosity parameter accelerates velocity whereas decelerates temperature profile. As the heat source parameter increases, the temperature of the fluid decreases for both suction and injection, it has been found. With the increasing values of the radiation parameter, the skin friction and heat transfer rate decreases. Increasing magnetic parameter decelerates the skin friction, Nusselt number, and Sherwood number.

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Radiation and Partial Slip Effects on Magnetohydrodynamic Jeffrey Nanofluid Containing Gyrotactic Microorganisms Over a Stretching Surface

Journal of Thermal Science and Engineering Applications ◽

10.1115/1.4048213 ◽

2020 ◽

Vol 13 (3) ◽

Author(s):

K. Kumaraswamy Naidu ◽

D. Harish Babu ◽

S. Harinath Reddy ◽

P. V. Satya Narayana

Keyword(s):

Nusselt Number ◽

Differential Equations ◽

Thermal Radiation ◽

Coupled System ◽

Partial Slip ◽

Stretching Surface ◽

Gyrotactic Microorganisms ◽

Similarity Transformations ◽

Jeffrey Nanofluid ◽

The Impact

Abstract In this study, the impact of thermal radiation and partial slip on magnetohydrodynamic flow of the Jeffrey nanofluid comprising motile gyrotactic microorganisms via vertical stretching surface is analyzed. The governing partial differential equations are reformed to a system of coupled ordinary differential equations by utilizing the similarity transformations. The transformed equations are of order four, which are complex to solve analytically and hence, the coupled system is solved computationally by using the shooting technique along the Runge–Kutta integrated scheme. The ramifications of different thermophysical parameters on the density of gyrotactic microorganisms, Jeffrey nanofluid velocity, nanoparticles concentration, temperature, Sherwood number, and Nusselt number are illustrated graphically. Comparing this study with the results already published favors the validity of this study. It is established that the Nusselt number is boosted on enhancing the thermal radiation parameter, and the reverse trend has been observed on increasing the Richardson number, whereas the gyrotactic microorganisms density is more in case of viscous nanofluid compared to the Jeffrey nanofluid.

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Impact of Nonlinear Thermal Radiation and the Viscous Dissipation Effect on the Unsteady Three-Dimensional Rotating Flow of Single-Wall Carbon Nanotubes with Aqueous Suspensions

Symmetry ◽

10.3390/sym11020207 ◽

2019 ◽

Vol 11 (2) ◽

pp. 207 ◽

Cited By ~ 25

Author(s):

Muhammad Jawad ◽

Zahir Shah ◽

Saeed Islam ◽

Jihen Majdoubi ◽

I. Tlili ◽

...

Keyword(s):

Boundary Layer ◽

Carbon Nanotubes ◽

Differential Equations ◽

Thermal Radiation ◽

Temperature Profile ◽

Viscous Dissipation ◽

Single Wall Carbon Nanotubes ◽

Nonlinear Thermal Radiation ◽

Aqueous Suspensions ◽

The Impact

The aim of this article is to study time dependent rotating single-wall electrically conducting carbon nanotubes with aqueous suspensions under the influence of nonlinear thermal radiation in a permeable medium. The impact of viscous dissipation is taken into account. The basic governing equations, which are in the form of partial differential equations (PDEs), are transformed to a set of ordinary differential equations (ODEs) suitable for transformations. The homotopy analysis method (HAM) is applied for the solution. The effect of numerous parameters on the temperature and velocity fields is explanation by graphs. Furthermore, the action of significant parameters on the mass transportation and the rates of fiction factor are determined and discussed by plots in detail. The boundary layer thickness was reduced by a greater rotation rate parameter in our established simulations. Moreover, velocity and temperature profiles decreased with increases of the unsteadiness parameter. The action of radiation phenomena acts as a source of energy to the fluid system. For a greater rotation parameter value, the thickness of the thermal boundary layer decreases. The unsteadiness parameter rises with velocity and the temperature profile decreases. Higher value of augments the strength of frictional force within a liquid motion. For greater and ; the heat transfer rate rises. Temperature profile reduces by rising values of .

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Influence of Hall Current and Thermal Radiation on MHD Convective Heat and Mass Transfer in a Rotating Porous Channel with Chemical Reaction

International Journal of Engineering Mathematics ◽

10.1155/2013/367064 ◽

2013 ◽

Vol 2013 ◽

pp. 1-13 ◽

Cited By ~ 8

Author(s):

Dulal Pal ◽

Babulal Talukdar

Keyword(s):

Magnetic Field ◽

Mass Transfer ◽

Thermal Radiation ◽

Heat And Mass Transfer ◽

Hall Current ◽

Perturbation Technique ◽

Porous Channel ◽

Physical Parameters ◽

Shear Stresses ◽

Resultant Velocity

A theoretical study is carried out to obtain an analytic solution of heat and mass transfer in a vertical porous channel with rotation and Hall current. A constant suction and injection is applied to the two insulating porous plates. A strong magnetic field is applied in the transverse direction. The entire system rotates with uniform angular velocity Ω about the axis normal to the plates. The governing equations are solved by perturbation technique to obtain the analytical results for velocity, temperature, and concentration fields and shear stresses. The steady and unsteady resultant velocities along with the phase differences for various values of physical parameters are discussed in detail. The effects of rotation, buoyancy force, magnetic field, thermal radiation, and heat generation parameters on resultant velocity, temperature, and concentration fields are analyzed.

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The Consequences of Thermal Radiation and Chemical Reactions on Magneto-hydrodynamics in Two Dimensions Over a Stretching Sheet with Jeffrey Fluid.

10.22541/au.163903063.31692115/v1 ◽

2021 ◽

Author(s):

Vijay Patel ◽

Jigisha Pandya

Keyword(s):

Differential Equations ◽

Thermal Radiation ◽

Ordinary Differential Equations ◽

Homotopy Analysis Method ◽

Stretching Sheet ◽

Fluid Velocity ◽

Jeffrey Fluid ◽

Analysis Method ◽

Homotopy Analysis ◽

The Impact

In this research paper, the Homotopy Analysis Method is used to investigate the twodimensional electrical conduction of a magneto-hydrodynamic (MHD) Jeffrey Fluid across a stretching sheet under various conditions, such as when electrical current and temperature are both present, and when heat is added in the presence of a chemical reaction or thermal radiation. Applying similarity transformation, the governing partial differential equation is transformed into terms of nonlinear coupled ordinary differential equations. The Homotopy Analysis Method is used to solve a system of ordinary differential equations. The impact of different numerical values on velocity, concentration, and temperature is examined and presented in tables and graphs. The fluid velocity reduces as the retardation time parameter(2) grows, while the fluid velocity inside the boundary layer increases as the Deborah number () increases. The velocity profiles decrease when the magnetic parameter M is increased. The results of this study are entirely compatible with those of a viscous fluid. The Homotopy Analysis Method calculations have been carried out on the PARAM Shavak high-performance computing (HPC) machine using the BVPh2.0 Mathematica tool.

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Energy and Temperature-Dependent Viscosity Analysis on Magnetized Eyring-Powell Fluid Oscillatory Flow in a Porous Channel

Energies ◽

10.3390/en14237829 ◽

2021 ◽

Vol 14 (23) ◽

pp. 7829

Author(s):

Meng Yang ◽

Munawwar Ali Abbas ◽

Wissam Sadiq Khudair

Keyword(s):

Thermal Radiation ◽

Perturbation Technique ◽

Three Dimensional ◽

Weissenberg Number ◽

Physical Parameters ◽

Temperature Dependent ◽

Temperature Dependent Viscosity ◽

Engineering Sciences ◽

Dependent Viscosity ◽

The Impact

In this research, we studied the impact of temperature dependent viscosity and thermal radiation on Eyring Powell fluid with porous channels. The dimensionless equations were solved using the perturbation technique using the Weissenberg number (ε ≪ 1) to obtain clear formulas for the velocity field. All of the solutions for the physical parameters of the Reynolds number (Re), magnetic parameter (M), Darcy parameter (Da) and Prandtl number (Pr) were discussed through their different values. As shown in the plots the two-dimensional and three-dimensional graphical results of the velocity profile against various pertinent parameters have been illustrated with physical reasons. The results revealed that the temperature distribution increases for higher Prandtl and thermal radiation values. Such findings are beneficial in the field of engineering sciences.

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Magnetohydrodynamic stagnation point on a Casson nanofluid flow over a radially stretching sheet

Beilstein Journal of Nanotechnology ◽

10.3762/bjnano.11.114 ◽

2020 ◽

Vol 11 ◽

pp. 1303-1315

Author(s):

Ganji Narender ◽

Kamatam Govardhan ◽

Gobburu Sreedhar Sarma

Keyword(s):

Heat Transfer ◽

Differential Equations ◽

Stagnation Point ◽

Radiation Effects ◽

Stretching Sheet ◽

Nonlinear Partial Differential Equations ◽

Casson Nanofluid ◽

Similarity Transformations ◽

Program Language ◽

The Impact

This article proposes a numerical model to investigate the impact of the radiation effects in the presence of heat generation/absorption and magnetic field on the magnetohydrodynamics (MHD) stagnation point flow over a radially stretching sheet using a Casson nanofluid. The nonlinear partial differential equations (PDEs) describing the proposed flow problem are reduced to a set of ordinary differential equations (ODEs) via suitable similarity transformations. The shooting technique and the Adams–Moulton method of fourth order are used to obtain the numerical results via the computational program language FORTRAN. Nanoparticles have unique thermal and electrical properties which can improve heat transfer in nanofluids. The effects of pertinent flow parameters on the nondimensional velocity, temperature and concentration profiles are presented. Overall, the results show that the heat transfer rate increases for higher values of the radiation parameter in a Casson nanofluid.

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