Impact of nonlinear radiation on magnetohydrodynamic flow of hybrid nanofluid with heat source effect

Sandeep, N.; Ranjana, B.; Samrat, S.P.; Ashwinkumar, G.P.

doi:10.1177/09544089211070667

Cited by 26 publications

(13 citation statements)

References 54 publications

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“…Interaction of thermal radiation on the natural convective flow via a cone by analyzing the properties of wall heat, as well as mass flux through a porous medium, was presented by Ghoneim et al 20 Tassaddiq et al 21 have studied the heat and mass transfer of hybrid nanofluid through a rotating disk. The Runge–Kutta method is an effective method for solving fluid flow problems which can be seen in the following papers 22–27 …”

Section: Introductionmentioning

confidence: 99%

“…The Runge-Kutta method is an effective method for solving fluid flow problems which can be seen in the following papers. [22][23][24][25][26][27] The fluid flows on a cone-shaped physique through a porous medium have inspired attention due to recent improvements in innovative technologies. Excellent applications for the effect of porous media may be found in a wide range of technical and industrial domains, including fiber spinning process, paper production, underground spreading of chemical waste, and nuclear waste repository.…”

Section: Introductionmentioning

confidence: 99%

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MHD flow in a rotating vertical cone through a porous medium

2022

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In the context of advancements in both heat and mass transfer, the current study intends to analyze the impacts of thermal radiation, Soret, and Dufour on the magnetohydrodynamic boundary layer flow through a vertical spinning cone in porous media. The Dufour effect is the energy flux due to the mass concentration gradient with a reciprocal phenomenon, the Soret effect. Energy expression considers the physical aspects of heat generation and absorption. It is expected that the tangential, circumferential, and normal directions will all have velocity components in flow through a porous media. The governing equations are nonlinear partial differential equations that are rearranged into ordinary differential equations via similarity transformation, and then they are numerically solved using the Runge–Kutta method along with a proper shooting strategy. Graphs are used to examine the impacts of many parameters on flow characteristic velocity, temperature, and concentration, including magnetic parameters, porous parameters, Dufour and Soret parameters, chemical reaction parameters, and more. The numerical findings of the gradient of velocity, the Nusselt and Sherwood numbers, and the surface drag force are tabulated and compared with the current result and the one from the literature. The findings are found to be in good agreement. Circumferential and normal velocities are improved visually for greater values of the porosity parameter, but the tangential velocity behavior of the magnetic parameter exhibits the reverse behavior. In addition, the Dufour parameter and chemical reaction both exhibit diminishing behavior when the Soret parameter increases.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

MHD flow in a rotating vertical cone through a porous medium

2022

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“…The oblique MHD nanoliquid flow past a nonlinear stretched cylinder is reported by Abbas et al 4 Vaidya et al 5 scrutinized the mixed convective MHD flow of nanoliquid toward a Riga sheet with a chemical reaction. The electrically conducting Jeffrey nanoliquid stream by perpendicular stretching cylinder is elucidated by Hayat et al 6 Sandeep et al 7 illustrated the influence of nonlinear radiative heat on MHD hybrid nanoliquid flow past an elongated surface. Sulochana and Mahalaximi 8 investigated the influence of chemical response as well as radiative heat on the flow of Williamson nanoliquid across an expandable sheet.…”

Section: Introductionmentioning

confidence: 99%

Application of heat transfer on MHD shear thickening fluid flow past a stretched surface with variable heat source/sink

Ramudu

Kumar²,

Sugunamma

2022

Heat Trans

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The purpose of this study is to explore the viscous dissipation stimulus on the steady convective magnetohydrodynamic shear thickening liquid stream across a vertically stretched sheet. The impact of thermic heat, first‐order velocity slip, and variable heat generation/absorption are considered and also ignored the effect of magnetic Reynold's number. We converted flow controlling equations into the set of dimensionless nonlinear ordinary differential equations by employing similarity variables to solve these coupled equations by R–K and shooting technique. The effect of different dimensionless variables on velocity, heat, friction factor, and local Nusselt numbers are presented through graphs and tables. Depreciation in velocity and growth in temperature distribution is detected when the Casson fluid parameter is increased. Temperature is the increasing function of the Eckert number.

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“…As depicted by Usman et al 9 the hybrid nanoparticles have superior thermal flow rate in comparison of nanofluid. Sundaeep et al 10 have deliberated influence of nonlinear thermal radiations upon MHD hybrid nanofluid flow subject to effects of heat source on a curved stretching sheet. Ashwinkumar et al 11 have deliberated convective thermal flow in MHD hybrid nanoparticles using two different geometrical views and have concluded that augmentation in thermal radiation factor and nanoparticles concentration have boosted the distributions of temperature.…”

Section: Introductionmentioning

confidence: 99%

A semi-analytical passive strategy to examine the water-ethylene glycol (50:50)-based hybrid nanofluid flow over a spinning disk with homogeneous–heterogeneous reactions

Algehyne

Altaweel

Saeed

et al. 2022

Sci Rep

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Scientists and researchers are much interested in studying graphene and silver nanoparticles for the enhancement of heat transport due to their extensive variety of applications in different areas of industrial and engineering such as drug delivery, medical devices, ultra-light, excellent electrical conductivity, strong medical strength, health care, consumer, food, etc. Therefore, in the existing investigation, the MHD flow of a mixed convective hybrid nanoliquid with graphene and silver nanoparticles past a rotating disk is considered. Water and ethylene glycol (50:50) is used as a base liquid in the existing model. The mechanism for heat transport is computed with the existence of thermal radiation and thermal convective condition. Homogeneous and heterogeneous chemical reactions are assumed in the flow behavior. The mathematical formulation of the proposed problem is based on the nonlinear PDEs which are then transformed to nonlinear ODEs by manipulating the appropriate similarity transformation. The simulation of the existing problem has been performed with the help of the homotopy analysis technique. The outcomes of the different flow parameters on the velocities, temperature, concentration, skin friction coefficient, and Nusselt number of the hybrid nanofluid are attained via graphs and tables. Some significant results from the existing problem demonstrate that the rate of heat transport is greater for the thermal Biot number and nanoparticles volume fraction. Further, it is noticed that the velocity of the liquid particles becomes lower for a higher magnetic field parameter.

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Impact of nonlinear radiation on magnetohydrodynamic flow of hybrid nanofluid with heat source effect

Cited by 26 publications

References 54 publications

MHD flow in a rotating vertical cone through a porous medium

MHD flow in a rotating vertical cone through a porous medium

Application of heat transfer on MHD shear thickening fluid flow past a stretched surface with variable heat source/sink

A semi-analytical passive strategy to examine the water-ethylene glycol (50:50)-based hybrid nanofluid flow over a spinning disk with homogeneous–heterogeneous reactions

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