Tangent hyperbolic nanofluid with mixed convection flow: An application of improved Fourier and Fick's diffusion model

Ibrahim, Wubshet; Gizewu, Tezera

doi:10.1002/htj.21589

Cited by 16 publications

(12 citation statements)

References 40 publications

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“…Constitutive equation of non-Newtonian fluid which is assumed in this article is presented by [66] as follows:…”

Section: Mathematical Formulationmentioning

confidence: 99%

“…Furthermore, behavior of incompressible magnetohydrodynamic flow tangent hyperbolic fluid with the effect of melting heat transfer in the stagnation point has been reported by Hayat et al [63], and the analysis of tangent hyperbolic material in the presence of both nanoparticles past an exponential surface with the heat, mass, and motile microorganisms transfer rate in the magnetohydrodynamic convective flow has been performed by Shafiq et al [64]. Moreover, Alaidrous et al [65] and Ibrahim and Gizewu [66,67] have studied tangent hyperbolic nanofluid past bidirectional extending surface under the application of some physical conditions such as thermal radiation, Joule heating, activation energy, and chemical reaction of high order by employing Cattaneo-Christov heat flux model. To our knowledge, no one has attempted to investigate the effect of three-dimensional thin film flow of tangent hyperbolic fluid with nonlinear mixed convection flow and entropy generation past stretching surface.…”

Section: Introductionmentioning

confidence: 96%

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Thin Film Flow of Tangent Hyperbolic Fluid with Nonlinear Mixed Convection Flow and Entropy Generation

Ibrahim

Gizewu

2021

Mathematical Problems in Engineering

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This paper examined the three-dimensional steady thin film flow of tangent hyperbolic fluid with nonlinear mixed convection flow and entropy generation past a stretching surface under the influence of magnetic field. For the flow problem, the Cattaneo–Christov heat and mass diffusion model was employed to examine heat and mass transfer characteristics and impacts of the normally directed magnetic field. To transform nonlinear PDEs into ODEs, the variable transformation technique was used. The bvp4c algorithm was implemented to solve these ODEs. The behavior of every leading parameter on the velocities, temperature, concentration profile, entropy generation, and Bejan number was reported with tabular and figurative form. The results show that as the values of Br increase, the entropy generation enhances, but the Bejan number decreases. Moreover, as the values of B increase, the opposite characteristics are observed in entropy generation and Bejan number graphs. Furthermore, the skin friction coefficient number, local Nusselt number, and Sherwood number are graphically discussed for the active involved parameters. The best agreement is recorded when we compare this paper with the previous literature for various values of M .

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“…Constitutive equation of non-Newtonian fluid which is assumed in this article is presented by [66] as follows:…”

Section: Mathematical Formulationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 96%

Thin Film Flow of Tangent Hyperbolic Fluid with Nonlinear Mixed Convection Flow and Entropy Generation

Ibrahim

Gizewu

2021

Mathematical Problems in Engineering

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“…All the equations of conservations formed according to Ibrahim and Gizewu 46 were used, which is given as the following:…”

Section: Mathematical Formulationmentioning

confidence: 99%

“…Hayat et al, 35 Khader and Megahed, 36 and Elbashbeshy et al 37 43 Saidulu et al, 44 and Shahzad et al 45 have studied MHD flow of a hyperbolic tangent fluid with the influence of heat source/sink, thermal radiation, nanoparticle, and chemical reaction past a stretching surface. And very recently, Ibrahim and Gizewu 46 have studied a tangent hyperbolic fluid with nanoparticles under the effect of mixed convection with Fick's and Fourier's theory.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear mixed convection flow of a tangent hyperbolic fluid with activation energy

Ibrahim

Gizewu

2020

Heat Trans

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In this communication, the dynamics of a non‐Newtonian tangent hyperbolic fluid with nanoparticles past a nonuniformly thickened stretching surface is discussed. We examine the impact of nonlinear mixed convection flow of a hyperbolic tangent fluid with the Cattaneo‐Christov heat and mass diffusion model past a bidirectional stretching surface. The effects of activation energy and magnetic field are incorporated in the analysis. The variables of transformations are used to change the nonlinear partial differential equations into ordinary differential equations (ODEs). Then, these ODEs are numerically solved using the Matlab routine of the bvp4c algorithm. The derailed analysis of the influences of the governing parameters on velocities along the x‐ and y‐axes, temperature and concentration profiles are presented using tables and figures. The outcomes of these parameters reveal that the velocities along the x‐ and y‐axes are decreased for the values of We increasing but the opposite behavior is observed as the value of A increases. The results also show that the values of e and N b rise as the temperature profiles increase. Similar influences are observed on the profile of concentration as the values of F and f rise. As the values of N 1 go from 0.27 to 0.25, the skin‐friction coefficient increases, and similarly, as N b goes from 0.3 to 0.1, − θ false′ false( 0 false) is enhanced.

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“…From this study, it is comprehended that velocity is a decreased for growing estimations of the Weissenberg number and magnetic parameter. Ibrahim and Gizewu 3 , addressed the Tangent hyperbolic nanofluid flow with double diffusion effects and a second-order slip condition at the boundary. Ramzan et al 4 discussed the second-order slip in the attendance of Cattaneo–Christov (C–C) heat flux and homogeneous–heterogeneous reactions with Tangent hyperbolic liquid flow.…”

Section: Introductionmentioning

confidence: 99%

Significance of Hall effect and Ion slip in a three-dimensional bioconvective Tangent hyperbolic nanofluid flow subject to Arrhenius activation energy

Ramzan

Gül

Chung

et al. 2020

Sci Rep

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The dynamics of partially ionized fluid flow subjected to the magnetic field are altogether distinct in comparison to the flow of natural fluids. Fewer studies are available in the literature discussing the alluring characteristics of the Hall effect and the Ion slip in nanofluid flows. Nevertheless, the flow of nanofluid flow with Hall and Ion slip effect integrated with activation energy, gyrotactic microorganisms, and Cattaneo–Christov heat flux is still scarce. To fill in this gap, our aim here is to examine the three dimensional electrically conducting Tangent hyperbolic bioconvective nanofluid flow with Hall and Ion slip under the influence of magnetic field and heat transmission phenomenon past a stretching sheet. Impacts of Cattaneo–Christov heat flux, Arrhenius activation energy, and chemical reaction are also considered here. For the conversion of a non-linear system to an ordinary one, pertinent transformations procedure is implemented. By using the bvp4c MATLAB function, these equations with the boundary conditions are worked out numerically. The significant impacts of prominent parameters on velocity, temperature, and concentration profiles are investigated through graphical illustrations. The results show that the velocity of the fluid is enhanced once the Ion slip and Hall parameters values are improved. Furthermore, the concentration is improved when the values of the activation energy parameter are enhanced.

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Tangent hyperbolic nanofluid with mixed convection flow: An application of improved Fourier and Fick's diffusion model

Cited by 16 publications

References 40 publications

Thin Film Flow of Tangent Hyperbolic Fluid with Nonlinear Mixed Convection Flow and Entropy Generation

Thin Film Flow of Tangent Hyperbolic Fluid with Nonlinear Mixed Convection Flow and Entropy Generation

Nonlinear mixed convection flow of a tangent hyperbolic fluid with activation energy

Significance of Hall effect and Ion slip in a three-dimensional bioconvective Tangent hyperbolic nanofluid flow subject to Arrhenius activation energy

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