MHD hybrid nanofluid flow with convective heat transfer over a permeable stretching/shrinking surface with radiation

Wahid, Nur Syahirah; Arifin, Norihan Md; Khashi’ie, Najiyah Safwa; Pop, Ioan; Bachok, Norfifah; Hafidzuddin, Ezad Hafidz

doi:10.1108/hff-04-2021-0263

Cited by 26 publications

(14 citation statements)

References 51 publications

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“…The internal heat generation and the electromagnetic field have been considered in the onedimensional energy balance equation of a convective-radiative trapezoidal porous fin. The corresponding governing heat equation is expressed by Equation (7). Using similarity terms, this equation and the boundary conditions are nondimensionalized.…”

Section: Resultsmentioning

confidence: 99%

“…The flow and heat transference of a hybrid nanoliquid with dust particles past a stretchy sheet was inspected by Reddy et al 2 Several necessary research studies have explained the performance of these liquids in the heat transfer process. [3][4][5][6][7][8] Using the extended surface is another way to improve the heat transfer rate. Extended surfaces/fins are widely used in the configuration and manufacturing of diverse heat machinery and materials, including air conditioning, gas turbines, computer processors, refrigeration, convectional furnaces, electrical chips, superheaters, power plants, heat exchangers, chemical processing equipment, oilcarrying pipelines, economizers, and automobiles.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, Reddy et al 1 expounded the heat transmission and radiative flow aspects of Casson nanoliquid through a cylindrical geometry. The flow and heat transference of a hybrid nanoliquid with dust particles past a stretchy sheet was inspected by Reddy et al 2 Several necessary research studies have explained the performance of these liquids in the heat transfer process 3–8 . Using the extended surface is another way to improve the heat transfer rate.…”

Section: Introductionmentioning

confidence: 99%

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Effect of electromagnetic field on the thermal performance of longitudinal trapezoidal porous fin using DTM–Pade approximant

et al. 2022

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The heat transfer and thermal distribution through porous fins have gotten a lot of attention in recent years due to their extensive applications in the manufacturing and engineering field. In porous fins, the impact of magnetic field aids in improved heat transfer enhancement. Also, the combination of an electric effect and a magnetic field considerably enhances heat transfer. In this direction, the thermal distribution through a convective–radiative longitudinal trapezoidal porous fin with the impact of an internal heat source and an electromagnetic field is discussed in the present analysis. The governing heat equation is nondimensionalized with nondimensional terms, and the transformed nonlinear ordinary differential equation is solved analytically using the DTM–Pade approximant algorithm. Furthermore, the graphical discussion is presented to explore the impact of various nondimensional parameters, such as convection‐conduction parameter, fin taper ratio, thermomagnetic field, radiation–conduction parameter, internal heat generation parameter, and thermoelectrical field on the temperature gradient of the fin. The investigation's key findings disclose that as the magnitude of the convection–conduction parameter, fin taper ratio, and radiation–conduction parameter increase, the thermal distribution through the fin reduces. The thermal distribution inside the fin increases for the heat‐generating parameter, thermoelectric, and thermomagnetic fields.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Effect of electromagnetic field on the thermal performance of longitudinal trapezoidal porous fin using DTM–Pade approximant

et al. 2022

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“…Zaib et al (2018) investigated the influence of convective condition on the time-dependent flow of Williamson nanofluid past a shrinkable sheet and found double solutions. Recently, Wahid et al (2021) imposed the convective condition on magnetohydrodynamic flow alongside the radiation effect induced by a hybrid nanofluid past a porous shrinkable/stretchable sheet.…”

Section: Introductionmentioning

confidence: 99%

MHD flow of a nanofluid due to a nonlinear stretching/shrinking sheet with a convective boundary condition: Tiwari–Das nanofluid model

Khan

Zaib

Pop

et al. 2022

HFF

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Purpose Nanofluid research has piqued the interest of scientists due to its intriguing applications in nanoscience, biomedical and electrical engineering, medication delivery, biotechnology, food processing, chemotherapy and other fields. This paper aims to inspect the behavior of the mixed convection magnetohydrodynamic flow and heat transfer induced by a nonlinear stretching/shrinking sheet in a nanofluid with a convective boundary condition. Tiwari and Das mathematical nanofluid model is incorporated in the analysis. Design/methodology/approach The mathematical model is initially transformed to a nondimensional form by using dimensionless variables. Then the nondimensional partial differential equations are further transformed to a set of similarity equations by using the similarity technique. These equations are solved numerically by the bvp4c function in MATLAB software. Findings For a certain range of the stretching/shrinking parameter, two solutions are obtained. The friction factor and the heat transfer rate escalate due to suction parameter with adding nanoparticles volume fraction by almost 27.15% and 0.153% for the upper branch solution, while the friction factor declines by almost 30.10% but the heat transfer rate augments by 0.145% for the lower branch solution. Furthermore, the behavior of the nanoparticle volume fractions on the heat transfer rate behaves differently in the presence of the mixed convection effect. The temperature of fluid augments with increasing Biot number for both solutions. Originality/value The present work considers the flow and heat transfer induced by a stretching/shrinking sheet in a nanofluid using the Tiwari–Das nanofluid model with a convective boundary condition, where the effect of the buoyancy force is taken into consideration. It is shown that two solutions are found for a certain range of the shrinking strength, while the solution is unique for the stretching case. This study is important for scientists working in the growing field of nanofluids to become familiar with the flow properties and behaviors of such nanofluids.

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“…Ali et al 34 investigated MHD hybrid nanofluid circulation with heat production through such a porous medium. Wahid et al 35 used radiation to investigate MHD-based nanofluid flow with temperature distribution across a permeable stretching sheet.…”

Section: Introductionmentioning

confidence: 99%

Investigation of 3D flow of magnetized hybrid nanofluid with heat source/sink over a stretching sheet

Farooq

Tahir

Waqas

et al. 2022

Sci Rep

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The thermal processes with inclusion of nanomaterials provide a wide range of applications pertaining to heat exchangers and cooling of compact heat density devices. The current research investigates the three-dimension flow of hybrid nanofluid comprising TC4(Ti-6A-14V) and Nichrome 80% Ni and 20% Cr nanoparticles mixed within engine oil as the base fluid for the enhancement of heat and mass transfer rate. The effects of homogeneous-heterogeneous processes and thermal radiation are incorporated. The heat transfer occurs due to a rotating inclined stretched sheet is discussed against prominent factors such as thermal radiation, inclined angle parameter, rotation parameter, and heat source/sink. The leading mathematical formulation consists of a set of PDEs, which are then transmuted into ordinary differential equations using suitable similarity transformation. The numerical solutions are obtained by using MATLAB's built-in function bvp4c. The results for velocity profile, temperature profile and concentration distribution are evaluated for suitable ranges of the controlling parameters. The graphical result shows that when the angle of inclination, magnetic parameter, and the volumetric concentration of hybrid nanomaterials increase the axial flow profile of the hybrid nanofluid is reduced. However, the rotation parameter reveals the opposite response. The temperature is intensified with an increment of heat source/sink, shape factors, and magnetic field parameter. For enhanced nanoparticle volumetric concentration, the temperature of the fluid rises up. The graphical validation is also illustrated using streamlines and statistical plots for hybrid nanofluid.

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MHD hybrid nanofluid flow with convective heat transfer over a permeable stretching/shrinking surface with radiation

Cited by 26 publications

References 51 publications

Effect of electromagnetic field on the thermal performance of longitudinal trapezoidal porous fin using DTM–Pade approximant

Effect of electromagnetic field on the thermal performance of longitudinal trapezoidal porous fin using DTM–Pade approximant

MHD flow of a nanofluid due to a nonlinear stretching/shrinking sheet with a convective boundary condition: Tiwari–Das nanofluid model

Investigation of 3D flow of magnetized hybrid nanofluid with heat source/sink over a stretching sheet

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