Numerical study of heat and mass transfer in MHD flow of nanofluid in a porous medium with Soret and Dufour effects

The present study probed the creation of heat energy and concentrating into Newtonian liquids across vertical 3D-heated plates. The role of the Soret and Dufour theories in concentrating and energy formulas is discussed. The role of hybrid nanoparticles is introduced to illustrate particle efficiency in terms of solute and thermal energy. It is removed a viscous dissipation process and a changing magnetic field. The proposed approach is motivated by the need to maximize solute and thermal energy uses in biological and industrial domains. The constructed system of (partial differential equations) PDEs includes concentration, momentum, and thermal energy equations within various thermal characteristics. Transformations are used to formulate the system of (ordinary differential equations) ODEs for solution. To assess various features vs various variables, a Galerkin finite element approach is used. Motion into nanoscale components is shown to be smaller than motion into hybrid nanoparticles. Furthermore, fluctuations in heat energy and solute particle counts are seen in relation to changes in Soret, Eckert, magnetic, and Dufour numbers. The basic finding is that the generation of thermal energy for hybridized nanomaterials is much higher.

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“… 65 Ref. 66 Present study 0.68 0.681052103137 0.681052103137 0.72141 0.723331807103 0.723331807103 0.82458 0.824720819103 0.824720819103 …”

Section: Numerical Methods and Code Validationmentioning

confidence: 86%

RETRACTED ARTICLE: Simulation of hybridized nanofluids flowing and heat transfer enhancement via 3-D vertical heated plate using finite element technique

Hafeez

Krawczuk

Shahzad

et al. 2022

Sci Rep

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“…Because of their importance in the research of liquids with low and medium molecular weight, these effects are extremely important. Based on the above‐mentioned applications, Qureshi et al 15 investigated the thermal and mass distribution in a magnetohydrodynamic (MHD) nanoliquid motion in the presence of S‐D effects. Seid et al 16 examined the multiple slips and S‐D effects in a vertical stretched surface in the occurrence of nanoliquid containing magnetized nanoparticles.…”

Section: Introductionmentioning

confidence: 99%

The physical impact of blowing, Soret and Dufour over an unsteady stretching surface immersed in a porous medium in the presence of ternary nanofluid

Yogeesha¹,

Megalamani²,

Gill

et al. 2022

Heat Trans

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This study discusses the thermal and mass dispersal of ternary unsteady nanofluid flow in the existence of Soret and Dufour effects over a stretched surface with the Stefan blowing (SB) effect in porous media. The "blowing effect" is created by a large number of molecules or nanoscale particles moving from one point to another. SB is a mass transfer of species application that gives the notion of the blowing effect, as well as the Soret and Dufour effects, which are also being considered in the current study. The governing equations that pose the problem are solved using appropriate similarity variables and then translated into ordinary differential equations. Runge-Kutta-Fehlberg 45 and the shooting process are used to solve the reduced equations. The effect of the different dimensionless restrictions on the relevant profiles is visually depicted. According to the analysis, the rise in the porosity constraint will decline the velocity of the fluid. The SB parameter directly influences velocity, thermal, and concentration profiles. The Soret constraint increases concentration, whereas the Schmidt number has the opposite effect. With the addition of solid volume fraction, the rate of mass transmission and surface drag force reduces while the rate of heat dispersion increases.

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“…The Casson fluid behaves like a Newtonian fluid by increasing the values of the Casson parameter 25 . The numerical study of heat transfer and mass concentration of the MHD flow of nanofluid embedded in a porous media was discussed by Qureshi, et al 26 , considering the Soret and Dufour effects. Saqib, et al 27 obtained exact solutions for the MHD flow of nanofluid.…”

Section: Introductionmentioning

confidence: 99%

Fractional model for MHD flow of Casson fluid with cadmium telluride nanoparticles using the generalized Fourier’s law

Sheikh

Ching

Khan

et al. 2021

Sci Rep

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The present work used fractional model of Casson fluid by utilizing a generalized Fourier’s Law to construct Caputo Fractional model. A porous medium containing nanofluid flowing in a channel is considered with free convection and electrical conduction. A novel transformation is applied for energy equation and then solved by using integral transforms, combinedly, the Fourier and Laplace transformations. The results are shown in form of Mittag-Leffler function. The influence of physical parameters have been presented in graphs and values in tables are discussed in this work. The results reveal that heat transfer increases with increasing values of the volume fraction of nanoparticles, while the velocity of the nanofluid decreases with the increasing values of volume fraction of these particles.

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Numerical study of heat and mass transfer in MHD flow of nanofluid in a porous medium with Soret and Dufour effects

Cited by 28 publications

References 31 publications

RETRACTED ARTICLE: Simulation of hybridized nanofluids flowing and heat transfer enhancement via 3-D vertical heated plate using finite element technique

RETRACTED ARTICLE: Simulation of hybridized nanofluids flowing and heat transfer enhancement via 3-D vertical heated plate using finite element technique

The physical impact of blowing, Soret and Dufour over an unsteady stretching surface immersed in a porous medium in the presence of ternary nanofluid

Fractional model for MHD flow of Casson fluid with cadmium telluride nanoparticles using the generalized Fourier’s law

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