Stagnation Point Flow of EMHD Micropolar Nanofluid with Mixed Convection and Slip Boundary

Atif, S. M.; Abbas, Muhammad; Rashid, Umair; Emadifar, Homan

doi:10.1155/2021/3754922

Cited by 16 publications

(5 citation statements)

References 36 publications

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“…Haroon et al [16] examined the effects of uniform magnetism and heat radiation on nanofluid flow, noting that magnetism impedes fluid flow. Atif et al [17] considered a micropolar-based nanofluid with thermal radiation and mixed convection, finding that magnetic field presence enhances flow temperature.…”

Section: Introductionmentioning

confidence: 99%

Numerical Comparison of Cu and Al\(_2\) O\(_3\) Nanoparticles in an MHD Water-based Nanofluid

Rutto,

Chepkwony,

Oke

2024

J. Eng. Res. Rep.

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In this study, the impact of Cu and Al2O3 nanoparticles in a water-based nanofluid are considered. The application of this can be found in biomedical sensors and drug delivery. Specifically, it investigates heat transfer in the MHD flow of two nanofluids (Cu-water and Al2O3-water) over an exponentially stretching surface. The study formulates a model and renders it dimensionless using Similarity Transformation. Numerical solutions are obtained using the MATLAB package bvp4c. The focus is on analysing the heat transfer rate variation with nanoparticle volume fraction. Results indicate that Cu-water nanofluid exhibits higher heat transfer rates and lower skin frictions compared to Al2O3-water nanofluid.

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Section: Introductionmentioning

confidence: 99%

Numerical Comparison of Cu and Al\(_2\) O\(_3\) Nanoparticles in an MHD Water-based Nanofluid

Rutto,

Chepkwony,

Oke

2024

J. Eng. Res. Rep.

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“…Hussain et al 12 examined the micropolar nanofluid via stretching sheets numerically. Following them, Patel et al , 13 Lund et al , 14 Atif et al 15 and numerous others have investigated various surfaces and angles of the micropolar nanofluid flow problem.…”

Section: Introductionmentioning

confidence: 99%

Stability analysis for heat transfer flow in micropolar hybrid nanofluids

Adilla Norzawary,

Soid,

Ishak

et al. 2023

Nanoscale Adv.

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“…Both researchers discovered that increasing the magnetic parameter (M) or electrical parameter (E) results in an increase in temperature distribution at a specific point of the flow region. Furthermore, Shahzada et al [29] also expanded on Hsiao [27] research by looking at the stagnation point flow of an EMHD micropolar nanofluid with mixed convection and slip boundary. Recent studies by Ishak et al [30] and Olanrewaju et al [31] examined the effects of thermal radiation on magnetohydrodynamic (MHD) flow of micropolar fluid towards a stagnation point on a vertical surface and found that thermal radiation and absorption has greater impact on the velocity, angular velocity and temperature field.…”

Section: Introductionmentioning

confidence: 99%

Computational Dynamics of Stagnation Point Flow of Micropolar Fluid Past Vertical Porous Plates

Timothy,

Seini,

Sulemana

2023

JAMP

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This work examines the flow of a micropolar fluid over a vertical porous plate at the MHD stagnation point under viscous dissipation, convective boundary conditions, and thermal radiation. The governing partial differential equations and a set of similarity parameters were used to transform them into ordinary differential equations. The Runge-Kutta fourth-order algorithm is used in conjunction with the Newton Raphson shooting technique to numerically solve the generated self-similar equations. Results were tabulated both numerically and graphically, and examples for different controlling factors are quantitatively analyzed. According to the study, the vortex viscosity parameter (k) causes the velocity profiles to rise while the magnetic parameter, suction parameter, and radiation parameter cause them to fall. In contrast, as the flow's suction and prandtl values rise, so do the magnetic parameter, radiation, and vortex viscosity, while the thickness of the thermal boundary layer decreases.

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Stagnation Point Flow of EMHD Micropolar Nanofluid with Mixed Convection and Slip Boundary

Cited by 16 publications

References 36 publications

Numerical Comparison of Cu and Al\(_2\) O\(_3\) Nanoparticles in an MHD Water-based Nanofluid

Numerical Comparison of Cu and Al\(_2\) O\(_3\) Nanoparticles in an MHD Water-based Nanofluid

Stability analysis for heat transfer flow in micropolar hybrid nanofluids

Computational Dynamics of Stagnation Point Flow of Micropolar Fluid Past Vertical Porous Plates

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