Characteristical analysis of MHD heat and mass transfer dissipative and radiating fluid flow with magnetic field induction and suction

Poddar, Saykat; Islam, Md. Minarul; Ferdouse, Jannatul; Alam, Mehtab

doi:10.1007/s42452-021-04452-4

Cited by 15 publications

(8 citation statements)

References 39 publications

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“…▪ The Mathematica and Wolfram codes are deployed in gaining the numerical solutions from analytical form. According to Poddar et al [29], the analogy of the Rosseland approximation in relation to the radiation heat fluctuation simplifies to…”

Section: Methods Of Solutionmentioning

confidence: 99%

Analysis and Simulation of Hydromagnetic Nano-Fluid Flow Passing an Inclined Heated Sheet

Uka¹,

Agbo²,

Omamoke³

et al. 2022

IJHT

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The examination of nano-fluid in recent time has been encouraging just as its research interest cuts across some disciplines such as mathematics, mechanical, chemical, civil engineering, physics, earth and natural sciences. Its applicability in the industrial and technological advancement helps in controlling the rate at which heat is conducted and diffuses in a given medium, as well as improving thermal transportation through convection, radiation and conduction. In this work, the analysis of hydromagnetic nano-fluid flow past an inclined heated surface with temperature dependent non-uniform heat source/sink and thermal radiation under heat and mass transmission perspective is considered. Adequate similarity variables are employed in recovering the nonlinear coupled ordinary differential equations (ODEs) from the partial differential equations (PDEs) which describe the equation of the boundary layer. The transformed equations (ODEs) are addressed both analytically and numerically with the aid of regular series approximation technique and Wolfram Mathematica package. The numerically simulated obtained results are graphically presented with legends. The computations opined that velocity declines while energy increases as the magnetic field number enhances. Similarly, improvement on angle of inclination, breeds velocity deceleration. Furthermore, the rate of energy transfer increases as the temperature dependent non-uniform parameters due to thermal generation enhances. In addition, the nanoparticle concentration decreases with increasing values of Schmidt and thermal radiation factors.

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Section: Methods Of Solutionmentioning

confidence: 99%

Analysis and Simulation of Hydromagnetic Nano-Fluid Flow Passing an Inclined Heated Sheet

Uka¹,

Agbo²,

Omamoke³

et al. 2022

IJHT

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show abstract

“…Some successful studies within a similar calculation framework can be found in Refs. [26][27][28][29][30][31].…”

Section: Calculation Techniquementioning

confidence: 99%

Ion-Slip Effects on Bingham Fluid Flowing Through an Oscillatory Porous Plate with Suction

Mollah¹,

Rasmussen²,

Poddar³

et al. 2021

MMEP

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“…Their results show that by raising the levels of Rayleigh number, the heat transfer amount is improved, but with the growing power‐law index and Hartmann number, the heat transfer rate diminishes for shear thinning, Newtonian, and shear thickening fluids. Using an efficient explicit finite difference method, Poddar et al 31 investigated the analysis of MHD boundary layer convective flow of heat radiating and dissipative fluid past an immeasurable plate of vertical shape having an IMF and Soret effect. They revealed that a rising magnetic parameter suppresses the IMF.…”

Section: Introductionmentioning

confidence: 99%

Theoretical study of ARRHENIUS‐controlled heat transfer flow on natural convection affected by an induced magnetic field in a micro‐channel

Hamza

Ojemeri

Ahmad

2023

Engineering Reports

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The current study analyzes the implications of an Arrhenius‐controlled heat transfer fluid on free convection in a micro‐channel confined by two immeasurable vertical parallel plates that are electrically non‐conductive due to an induced magnetic field (IMF) effect. The governing coupled nonlinear equations are ordinary differential equations, and the dimensionless steady‐state solutions were determined using the homotopy perturbation method (HPM). The derived results were discussed and represented graphically with the help of illustrative line graphs for momentum, IMF, temperature, and volume flow rate for the major controlling parameters, namely arrhenius kinetics, rarefaction, wall ambient temperature difference ratios, and Prandtl magnetic number. Thermo‐physical properties that are of engineering interest, like sheer stress and Nusselt number, are also computed and displayed. It is pertinent to report that the velocity of the fluid increases as a result of chemical reactions and rarefaction factors, whereas strengthening the Prandtl magnetic number decreases the volume flow rate. Also, numerical data was obtained and presented in tabular form to compare this research outcome to those of Jha and Aina, and great consistency was found. Microelectronics and microfluidics are some areas where this study can find relevance.

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Characteristical analysis of MHD heat and mass transfer dissipative and radiating fluid flow with magnetic field induction and suction

Cited by 15 publications

References 39 publications

Analysis and Simulation of Hydromagnetic Nano-Fluid Flow Passing an Inclined Heated Sheet

Analysis and Simulation of Hydromagnetic Nano-Fluid Flow Passing an Inclined Heated Sheet

Ion-Slip Effects on Bingham Fluid Flowing Through an Oscillatory Porous Plate with Suction

Theoretical study of ARRHENIUS‐controlled heat transfer flow on natural convection affected by an induced magnetic field in a micro‐channel

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