A computational analysis of dissipation effects on the hydromagnetic convective flow of hybrid nanofluids along a vertical wavy surface

Iqbal, Muhammad Saleem; Mustafa, Irfan; Ghaffari, Abuzar; Usman, Usman

doi:10.1002/htj.22265

Cited by 11 publications

(3 citation statements)

References 57 publications

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“…The chemical reaction process and its influence on the mathematical model of three-dimensional (3D) Casson nanofluid with attached Brownian motion, thermal radiation, and velocity slip over stretched sheet are discussed by Umar et al 32 Latest studies related to the chemical process with magnetized mixture fluid and hydromagnetic Reiner-Rivlin nanofluid are discussed by Khan et al 33,34 Iqbal et al 35 did work on carbon nanotubes and heat transport analysis with associated geometry of rotating and stretchable disk. Further they 36,37 worked on nanofluid along with chemical process and effects on the hydromagnetic convective flow attached with a vertical wavy surface. Ghaffari et al 38,39 made their recent investigations related to entropy generation with chemical reaction impact and transfer of energy by increasing thermal conductivity associated with powerlaw nanofluid.…”

Section: Introductionmentioning

confidence: 99%

Characterization of Cross nanofluid based on infinite shear rate viscosity with inclination of magnetic dipole over a three‐dimensional bidirectional stretching sheet

Darvesh

Altamirano

Chero³

et al. 2022

Heat Trans

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Fluid viscosity manages several engineering processes and keeps its leading role in lubrication models, biological models, polymer processes, melt solutions, colloidal suspensions, and mayonnaise. The cross viscosity model is the most appropriate model, which interprets the key features of non-Newtonian fluids in the region of shear-thinning/thickening when very high and very low shear rates are applied. This article focuses on the mathematical model of threedimensional Cross nanofluid and interprets its aspect of infinite shear rate of viscosity over the expanding sheet. Velocity is studied through placing inclined magnetic dipole effect, transportation phenomenon is brought by considering the radiation effects, heat generation and chemical process is engaged for concentration of nanoparticles. The geometry of this mathematical model is expanding the stretching sheet with velocity slip, and convective heat conditions are associated. Similarity variables are being utilized for conversion dimensional mathematical model into nondimensional one. For the pursuit of numerical solution of the system of nondimensional

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Section: Introductionmentioning

confidence: 99%

Characterization of Cross nanofluid based on infinite shear rate viscosity with inclination of magnetic dipole over a three‐dimensional bidirectional stretching sheet

Darvesh

Altamirano

Chero³

et al. 2022

Heat Trans

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“…Concern with the related investigation many researchers did a tremendous job in the computational analysis of nanofluids. Beside a vertical wavy surface, Iqbal et al [48] discussed a computational investigation of dissipation influences on the flow of hydro magnetic convective of hybrid nanofluids. Similarly, Ghaffari et al [49] analyzed entropy generation above a stretchable rotatory permeable disk in a flow of power-law nanofluid.…”

Section: Introductionmentioning

confidence: 99%

Comparative Evaluation of the Optimal Auxiliary Function Method and Numerical Method to Explore the Heat Transfer between Two Parallel Porous Plates of Steady Nanofluids with Brownian and Thermophoretic Influences

Ullah

Khan

Fiza

et al. 2022

Mathematical Problems in Engineering

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In this study, we used the newly established optimal approach, namely, optimal auxilary function method (OAFM) along with the Adams numerical solver technique in order to investigate the heat transfer between two permeable parallel plates of steady nanofluids (HTBTP-SNFs) through Brownian and thermophoretic consequences. The new scheme model (HTBTP-SNFs) in terms of partial differential equations (PDEs) is changed to nonlinear ordinary differential equations (ODEs) by utilizing similarity transformations. The OAFM and Adams numerical methods are used to solve the resulting ODEs with boundary conditions. The OAFM along with convergence and Adams numerical method are studied in detail. The influences of the physical parameters of HTBTP-SNFs model for instance porosity parameter (m), parameter of magnetic (M), parameter of Brownian (Nb), viscosity parameter (R), Schmidt number (Sc), thermophores parameter (Nt), and Prandlt number (Pr) are discussed with the help of tabular data and graphs. The reliability and effectiveness of the technique are achieved by equating the results available in the literature.

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“…Ibrahim and Tulu 9 have investigated the effect of heat transfer on flow through a wedge with viscous dissipation. Ohmic heating in convective free‐flow MHD with consideration of chemical effects was examined by Deka et al 10 Iqbal et al, 11 and Pandey and Kumar 12 have contributed to the evaluation of the effects of viscous dispersion for different types of flow. Results of chemical reaction along with other relevant parameters have been suggested by Kandasamy and Devi, 13 Mishra et al, 14 and Pandey and Kumar 15 …”

Section: Introductionmentioning

confidence: 99%

Disquisition of thermophoresis and chemical reaction sketch in viscous stream over a wedge

Deka

Choudhury

2022

Heat Trans

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A computative exploration is engraved on synchronized heat and mass transmission in a stream across a wedge. The problem has been executed for MHD incompressible viscous fluid, which annexes the impact of thermophoresis. The sequels of chemical reactions and energy sources have also been encountered. The resulting equations are transmuted as nondimensional forms and a numerical method is executed to solve the same. The numerical results for velocity, temperature, and concentration distributions are illustrated in the form of graphs for various dimensionless parameters affecting the problem. Numerical data are computed for skin friction coefficient, Nusselt number, and Sherwood number for different parameters. The results have been depicted for possible cases by means of pictorial visualizations. The present study has importance in various sectors of industrial and engineering applications.

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A computational analysis of dissipation effects on the hydromagnetic convective flow of hybrid nanofluids along a vertical wavy surface

Cited by 11 publications

References 57 publications

Characterization of Cross nanofluid based on infinite shear rate viscosity with inclination of magnetic dipole over a three‐dimensional bidirectional stretching sheet

Characterization of Cross nanofluid based on infinite shear rate viscosity with inclination of magnetic dipole over a three‐dimensional bidirectional stretching sheet

Comparative Evaluation of the Optimal Auxiliary Function Method and Numerical Method to Explore the Heat Transfer between Two Parallel Porous Plates of Steady Nanofluids with Brownian and Thermophoretic Influences

Disquisition of thermophoresis and chemical reaction sketch in viscous stream over a wedge

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