Joule Heating and Dissipation Effects on Magnetohydrodynamic Couple Stress Nanofluid Flow over a Bidirectional Stretching Surface

Tarakaramu, Nainaru; Narayana, P. V. Satya; Babu, D. Harish; Sarojamma, G.; Makinde, Oluwole Daniel

doi:10.18280/ijht.390122

Cited by 22 publications

(9 citation statements)

References 40 publications

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“…The authors revealed that the heat transfer rate reduces with increasing slip and magnetic parameters. Tarakaramu et al 9 have examined the nonlinear thermal radiation effects on MHD flow. Authors have solved the governing boundary layer equations by using similarity transformation along with Runge–Kutta–Fehlberg (RKF) and shooting method, also authors have indicated the significance of Eckert number on temperature distributions.…”

Section: Introductionmentioning

confidence: 99%

Stability analysis of MHD radiative mixed convective flow in vertical cylindrical annulus: Thermal nonequilibrium approach

Shilpa

Leela

Rani³

2022

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In the present study, the influence of the induced magnetic field on the MHD mixed convective electrically conducting fluid flow inside the vertical cylindrical annulus is analyzed numerically. The heat transfer is presumed to be due to a combination of mixed convection and radiation. The stability of the flow is examined when the solid and fluid phases are not in local thermal equilibrium. The governing equations are solved numerically by both finite difference and finite element methods. To control the flow formation rate more accurately the induced magnetic field is also considered in this study. As the magnetic Prandtl number (Pm) and Hartmann number (M) get enhanced, the velocity and induced magnetic fields get retarded in the annulus due to the presence of drag‐like force, namely, the Lorentz force. When there is an increase in the mixed convection parameter the induced magnetic field gets enhanced. An increase in radiation parameter tends to decline the fluid temperature and reverse the behavior of the solid temperature. Increment in Pm decreases the wall shear stress near the conducting cylinder. Increasing values of porous, magnetic, and radiation parameters lead to an unstable system with smaller heat transfer coefficient values but the system gets stabilized for larger values of heat transfer coefficient. The results could be used as first‐hand information for comprehending and developing the thermal flow phenomenon in porous media. The obtained numerical results are in good accordance with the existing results. Using an artificial neural network, heat transfer characteristics are analyzed through mean square error and regression analysis.

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Section: Introductionmentioning

confidence: 99%

Stability analysis of MHD radiative mixed convective flow in vertical cylindrical annulus: Thermal nonequilibrium approach

Shilpa

Leela

Rani³

2022

Heat Trans

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“…Sithole et al 16 described the aspects of viscous dissipation on MHD second‐grade nanofluid flow over an elongating surface considering nonlinearly varying thermal radiation and convective heating condition. Viscous and Ohmic dissipation influences on free convective magnetized nanofluid flow past a cone with suction were analyzed by Upreti et al 17 Tarakaramu et al 18 demonstrated the viscous‐Ohmic dissipation, Lorentz force, and nonlinear thermal radiation impacts on couple stress nanofluid flow past a stretching sheet with zero mass flux boundary condition. Upreti et al 19 described the thermal radiation and viscous dissipation influences on the three‐dimensional flow of hybrid nanofluid along a convectively heated bidirectional elongating surface.…”

Section: Introductionmentioning

confidence: 99%

Aspects of second‐order velocity slip and radiation absorption on hydromagnetic stagnation point flow of Jeffrey fluid with chemical reaction

2022

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The present article describes the magnetohydrodynamic flow of a moving Jeffrey fluid along a convectively heated porous stretching surface with second‐order velocity slip and radiation absorption effects. Furthermore, chemical reactions and viscous dissipation impacts are also taken into account. The governing equations are converted into dimensionless ordinary differential equations (ODEs) using appropriate similarity transformations. The highly nonlinear ODEs are solved numerically by employing a shooting technique based on the Runge–Kutta Cash–Karp formula. The figures are used to study the variations in temperature, velocity, and concentration profiles for several physical factors. The numerical values of the local skin friction, Sherwood number, and Nusselt number are explained and shown in tables. The analysis reveals that the velocity profile is enhanced for amplifying values of velocity ratio parameter and first‐order velocity slip parameter. However, the temperature profile of Jeffrey nanofluid is highlighted w.r.t. Eckert number and radiation absorption parameter. This study may find significant applications in polymer production, food processing, instrumentation, combustion modeling, catalytic chemical reactors, and so on.

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“…Multiple slip effect together with microorganism is taken by Waqas et al 33 The drift is considered over the porous rotating disk and it is remarked that thermal, as well as the concentration boundary layer, is suppressed by thermal and concentration slip parameter. More research is done taking multiple slip conditions over a stretching sheet, cone, and slandering surface 34–42 …”

Section: Introductionmentioning

confidence: 99%

“…More research is done taking multiple slip conditions over a stretching sheet, cone, and slandering surface. [34][35][36][37][38][39][40][41][42] A numerical investigation is done for various geometries and under different conditions to get a suitable heat pass-on rate. Sometimes external heat sources are also clutched into an inspection to obtain suitable results.…”

Section: Introductionmentioning

confidence: 99%

Influence of multiple slips on magnetically driven nanofluid flow over an externally heated stretching cylinder

Maity

Kundu

2022

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In this article, we have inspected multiple slippery consequences along a stretching cylinder. Brownian migration along with thermophoresis is clutched together with an external heat source. Magnetic influence is considered perpendicular to the cylinder. Standard flow systems are transfigured to ordinary differential equations by well‐qualified similarity transformations. They are solved by the Runge–Kutta scheme of the fourth‐order (shooting technique) method with the assistance of MAPLE software. The entire simulation is done with a proper accuracy rate and the upshots are portrayed by graphs and tables. All results are compared under no slip and with slip provisions. Augmentation in Reynolds number and magnetic parameter uprise the velocity lines and the slip effect reduces the magnitude decently. The thermal jump effect reduces the magnitude of the heat transfer rate. The solutal slip effect decreases the concentration boundary layer for magnetic and Brownian migration specifications. Approximately 6.69% and 6.79% drop in Nusselt number is spotted for Brownian migration and thermophoresis parameters. The external heat source parameter brings out 14.98% inflation in the Nusselt number significantly.

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Joule Heating and Dissipation Effects on Magnetohydrodynamic Couple Stress Nanofluid Flow over a Bidirectional Stretching Surface

Cited by 22 publications

References 40 publications

Stability analysis of MHD radiative mixed convective flow in vertical cylindrical annulus: Thermal nonequilibrium approach

Stability analysis of MHD radiative mixed convective flow in vertical cylindrical annulus: Thermal nonequilibrium approach

Aspects of second‐order velocity slip and radiation absorption on hydromagnetic stagnation point flow of Jeffrey fluid with chemical reaction

Influence of multiple slips on magnetically driven nanofluid flow over an externally heated stretching cylinder

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