Numerical Investigation of Natural Convection Viscoelastic Jeffrey’s Nanofluid Flow from a Vertical Permeable Flat Plate with Heat Generation, Thermal Radiation, and Chemical Reaction

Agbaje, T. M.

doi:10.1155/2020/9816942

Cited by 3 publications

(2 citation statements)

References 55 publications

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“…Agbaje TM et al [5] Researched natural convection viscoelastic Jeffrey's nanofluid flow from a vertical permeable flat plate with heat generation, thermal radiation and chemical reaction. The findings depicted that Debora number and suction parameter had related effects on the velocity profile.…”

Section: Introductionmentioning

confidence: 99%

Magnetohydrodynamic Jeffrey Nanofluid Flow Over a Vertical Sheet

Simon

Mutuku

2022

ARJOM

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Aim: This study focuses on the numerical analysis of Jeffrey nano-fluid bound with magnetic field in presence of convectively heated boundary. Study Design: Abstract, introduction, Equations formulation, numerical analysis and conclusion Place and Duration of Study: Department of Mathematics and Actuarial Science, Kenyatta University, between 2021-2022 Methodology: This paper discusses the imposed magnetic field on Jeffrey fluid suspended with nanometre-sized particles moving over a vertical sheet with a convectively heated boundary. The partial differential equations are formulated by considering assumptions and the boundary conditions to describe the continuity, momentum, energy and concentration of the fluid. The similarity transformation technique was applied to convert the partial differential equations into first-order linear differential equations which were simulated in Matlab by invoking the Adam’s-Moulton predictor-corrector scheme in ode113. The graphs have been analysed with the effects of Deborah, Dufour-Lewis, Hartman, and Prandtl numbers respectively, solutal stratification, diffusion, thermophoresis, temperature Grashof, mass Grashof, relaxation-retardation parameters on the flow velocity, concentration, temperature, skin friction, heat and mass transfers looked into. Results: While Deborah number increased velocity, it reduced concentration, skin friction and thermal boundary layer at lower numbers hence improved mass and heat transfer. Solutal stratification, Retardation-relaxation parameter and diffusion raised temperature thus heat transfer. Conclusion: Deborah number, solutal stratification, retardation-relaxation parameter and diffusion improves heat and mass transfer.

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Section: Introductionmentioning

confidence: 99%

Magnetohydrodynamic Jeffrey Nanofluid Flow Over a Vertical Sheet

Simon

Mutuku

2022

ARJOM

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“…This happens because the more significant the magnetic variation, the more nanoparticles increase. The effect of heat generation and thermal radiation on nanofluids flow was used in [7], [8]. Maxwell nanofluid flow with Copper (Cu) and Titanium (Ti) nanoparticles were carried out [9], and it was found that the volume fraction affects the fluid temperature.…”

Section: Introductionmentioning

confidence: 99%

Numerical results of Crank-Nicolson scheme on unsteady nano fluid under the effect of Prandtl, Mixed Convection, and Magnetohydrodynamics

Ghani

Norasia

Anggriani

et al. 2022

IJCSAM

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In this paper, we are interested in the numerical results on the temperature and velocity profiles over a sphere of unsteady nano fluid by dealing with the effect of Prandtl, mixed convection, and magnetohydrodynamics. We first employ the boundary layer theory to establish the continuity, momentum, and energy equations. We further solve those differential equations numerically by using the finite difference scheme of Crank-Nicolson and Thomas algorithm for the iteration technique. The temperature and velocity profiles are established graphically for the variations of Prandtl, mixed convection, and magnetohydrodynamics. The velocity profile decreases when the variations of Prandtl numbers increase. Moreover, the velocity profiles increase when the variations of mixed convection and magnetohydrodynamics are increased. The temperature profiles are decreased for all variations of Prandtl numbers, mixed convection and magnetohydrodynamics.

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