An Analytical Study of Internal Heating and Chemical Reaction Effects on MHD Flow of Nanofluid with Convective Conditions

Rasheed, Haroon Ur; Islam, Saeed; Helmi, Maha M.; Alsallami, Shami A. M.; Khan, Zeeshan; Khan, İlyas

doi:10.3390/cryst11121523

Cited by 17 publications

(6 citation statements)

References 38 publications

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“…Thus, when the value of p changes continuously from 0 to 1, the homotopy solution also runs from initial guess 𭟋 0 (ξ), Θ 0 (ξ), and Φ 0 (ξ) to the accurate solution, 𭟋(ξ), Θ(ξ), and Φ(ξ) according to Liao [53]. As Haroon Ur Rasheed [54] did, we expand using Taylor series expansion rule about p = 0, and hence we have the following results.…”

Section: 𭟋(ξ;mentioning

confidence: 99%

Mathematical Analysis of Convective Heat Exchanger from Renewable Sun’s Radiation through Nano-fluid in Direct Absorption Solar Collectors with the Procreation of Entropy.

Tafesse

Daba

Naidu

2022

Preprint

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Now a days the high demand of energy cause the climate change which affect the living style of the people in the world. To mitigate this cases, the usage of renewable energy like solar energy plays a key role. In the application of thermal radiation, the work done is not 100% efficient due to the procreation of entropy. In this investigation, the researchers examined the heat and mass transfer from sun’s radiation through direct absorption into nanofluid with the creation of entropy. The mathematical governed partial differential equations are simplified by the use of similarity transformation variable which yields system of ordinary differential equations. To provide the solution for this problem, the wellknown analytic method called Homotopy Analysis Method implemented on Mathematica 12.1 based on the BVPh2.0 package. The validity of thisresult can be justified by comparing the solutions with different publishedarticles for specific values. From this study, we perceived that the transfer of heat from sun’s radiation is proliferated with multiple production of entropy. Thus, to gain the fruitful usage of renewable solar energy, weneed to maximize the heat transfer and minimize the creation of entropy. Keywords: Convective, Renewable Energy, DASC, Nanofluid, Entropy

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Section: 𭟋(ξ;mentioning

confidence: 99%

Mathematical Analysis of Convective Heat Exchanger from Renewable Sun’s Radiation through Nano-fluid in Direct Absorption Solar Collectors with the Procreation of Entropy.

Tafesse

Daba

Naidu

2022

Preprint

View full text Add to dashboard Cite

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“…Several researchers have examined the characteristics of fluid flow and heat transmission in numerous technical applications [1][2][3][4]. In the last decade, high-conductivity nanoparticles have been presented as a means of enhancing heat transmission [5][6][7][8]. The dissolving of nanoparticles in the base fluid produces a fluid known as a nanofluid.…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulations of Magnetohydrodynamics Natural Convection and Entropy Production in a Porous Annulus Bounded by Wavy Cylinder and Koch Snowflake Loaded with Cu–Water Nanofluid

et al. 2022

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The current paper presents a numerical study of the magnetohydrodynamics natural convection and entropy production of Cu–water nanofluid contained in a porous annulus between a heated Koch snowflake and wavy cylinder with lower temperature with respect to the Koch snowflake. The numerical algorithm is based on the Galerkin Finite Element Method. The impacts of Rayleigh number (Ra = 103, 104, 105, and 106), Hartman number (Ha = 0, 25, 50, and 100), Darcy number (Da = 10−2, 10−3, 10−4, and 10−5), nanoparticle volumetric fraction (φ = 2%, 3%, 4%, and 5%), and the undulations number of the outer wavy cylinder (three cases) on the distributions of isotherms, streamlines, mean Nusselt number (Nuavg), as well as on total entropy production and Bejan number are thoroughly examined. The computational outcomes disclose that dispersing more Cu nanoparticles in the base fluid and creating a flow with higher intensity inside the annulus by raising the Rayleigh number bring about a boosted natural convective flow in the cavity, which improves the heat transmission rate. In addition, it can be noted that owing to the peculiar form of the heated Koch snowflake, nanofluid gets trapped between the angled parts, resulting in uneven temperature profiles with higher values in these places.

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“…In this problem, they found that the augmented approximation of the porosity term decreased the nanoliquid Nusselt number. Rasheed et al 44 used the convective conditions and internal heating source for the flow of a nanoliquid. It was seen that the expansion in the magnetic parameter led to improving the thermal profile of the nanoliquid.…”

Section: Introductionmentioning

confidence: 99%

Computational Assessment of Microrotation and Buoyancy Effects on the Stagnation Point Flow of Carreau–Yasuda Hybrid Nanofluid with Chemical Reaction Past a Convectively Heated Riga Plate

et al. 2022

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The present framework deliberated the mixed convection stagnation point flow of a micropolar Carreau–Yasuda hybrid nanoliquid through the influence of the Darcy-Forchheimer parameter in porous media toward a convectively heated Riga plate. In this investigation, blood is used as a base liquid and gold (Au) and copper (Cu) are the nanoparticles. The main novelty of the present investigation is to discuss the transmission of heat through the application of thermal radiation, viscous dissipation, and the heat source/sink on the flow of a micropolar Carreau–Yasuda hybrid nanoliquid. Further, the results of the chemical reaction are utilized for the computation of mass transport. Brownian motion and thermophoretic phenomena are discussed in the current investigation. The current problem is evaluated by using the connective and partial slip conditions and is formulated on the basis of the higher-order nonlinear PDEs which are converted into highly nonlinear ODEs by exploiting the similarity replacement. In the methodology section, the homotopic analysis scheme is employed on these resulting ODEs for the analytical solution. In the discussion section, the results of the different flow parameters on the velocity, microrotation, energy, and mass of the hybrid nanofluid are computed against various flow parameters in a graphical form. Some of the main conclusions related to the present investigation are that the velocity profile is lowered but the temperature is augmented for both nanoparticles volume fractions. It is notable that the skin friction coefficient is reduced due to the higher values of the Darcy-Forchheimer parameter. Further, the rising performance of the hybrid nanofluid Nusselt number is determined by the radiation parameter.

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An Analytical Study of Internal Heating and Chemical Reaction Effects on MHD Flow of Nanofluid with Convective Conditions

Cited by 17 publications

References 38 publications

Mathematical Analysis of Convective Heat Exchanger from Renewable Sun’s Radiation through Nano-fluid in Direct Absorption Solar Collectors with the Procreation of Entropy.

Mathematical Analysis of Convective Heat Exchanger from Renewable Sun’s Radiation through Nano-fluid in Direct Absorption Solar Collectors with the Procreation of Entropy.

Numerical Simulations of Magnetohydrodynamics Natural Convection and Entropy Production in a Porous Annulus Bounded by Wavy Cylinder and Koch Snowflake Loaded with Cu–Water Nanofluid

Computational Assessment of Microrotation and Buoyancy Effects on the Stagnation Point Flow of Carreau–Yasuda Hybrid Nanofluid with Chemical Reaction Past a Convectively Heated Riga Plate

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