Melting and viscous dissipation effect on upper‐convected Maxwell and Williamson nanofluid

Ibrahim, Wubshet; Negera, Mekonnen

doi:10.1002/eng2.12159

Cited by 14 publications

(7 citation statements)

References 36 publications

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“…Among these models, existing literature shows little consideration has been made to the upper convected Maxwell (UCM) model, which is a sub‐arrangement of the rate‐type fluid. In 2020, Ibrahim and Negera 26 investigated the impact of chemical reaction, melting and viscous dissipation on Williamson and UCM nanofluids over an expanding sheet in porous medium. They showed that melting profoundly influences boundary layer velocity of Williamson nanofluid when contrasted with UCM nanofluid.…”

Section: Introductionmentioning

confidence: 99%

Critical points and stability analysis in MHD radiative non‐Newtonian nanoliquid transport phenomena with artificial neural network prediction

Rana

Bhardwaj

Makkar

et al. 2022

Math Methods in App Sciences

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In the present framework, flow and thermal transport behavior of non-Newtonian viscoelastic fluid induced by stretching/shrinking of the horizontal sheet under the influence of Lorentz force, volumetric heat source/sink, and radiation (assuming optically thick medium) has been investigated. Multiple solutions (Branches) have been predicted numerically using Lie symmetry transformation and Runge Kutta Dormand Prince (RKDP) algorithm-based Shooting method for the different controlling parameters, stretching/shrinking (𝛾 c < −1 < 𝛾 < ∞), and suction (𝛼 c < 𝛼 < ∞) with substantial impact with UCM parameter, 𝛽 > 0. Some of the results have also been compared with MATLAB built-in solvers to validate our in-house code. The deviations in critical (turning) points (𝛽 c , 𝛾 c ) have been noticed for different values of M and 𝛼. The temporal stability analysis is performed for these parameters (𝛽, 𝛾), and the upper (lower) branch is only physically feasible (infeasible). The combined effect on Nusselt number and skin-friction coefficient is also depicted in the form of contour plots. The outcomes from artificial neural network (ANN) using Levenberg-Marquardt algorithm give a preferred estimate for current numerical simulation. In ANN prediction, the optimal number of neurons in the hidden layer is used, having minimum value of RMSE and RMRE with maximum R 2 for different cases of non Newtonian stretching/shrinking sheet. Finally, the results conclude that the applied ANN model can accurately predict the output results.

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Section: Introductionmentioning

confidence: 99%

Critical points and stability analysis in MHD radiative non‐Newtonian nanoliquid transport phenomena with artificial neural network prediction

Rana

Bhardwaj

Makkar

et al. 2022

Math Methods in App Sciences

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“…It is a new major that is used in the aerospace industry. In addition, MHD is one of the methods that can influence heat and flow on a stretching sheet 1–5 . Naikoti Kishan et al 6 investigated MHD impact the warm exchange over a extending sheet rooted in a permeable medium with variable viscosity.…”

Section: Introductionmentioning

confidence: 99%

“…In addition, MHD is one of the methods that can influence heat and flow on a stretching sheet. [1][2][3][4][5] Naikoti Kishan et al 6 investigated MHD impact the warm exchange over a extending sheet rooted in a permeable medium with variable viscosity. Similarly, Stanford Shateyi et al 7 focused on the numerical investigation of three-dimensional MHD nanofluid stream over a extending sheet with convective boundary circumstances by means of a permeable medium..…”

Section: Introductionmentioning

confidence: 99%

Examination of warm transfer on extending sheet by variation iteration method strategy and investigation of arrangements for optimizing liquid properties

Pasha

Alibak

Nabi

et al. 2022

Engineering Reports

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This study aimed at investigating the variation of heat transfer and velocity changes of the fluid flow along the vertical line on a surface drawn from both sides. In the beginning, several parameters such as Prandtl number and viscoelastic effect were evaluated for heat transfer and fluid velocity by the variation iteration method. The results were compared with the numerical method. The second part of the description relates to the use Response surface method (RSM method) in the Design Expert software. In this paper, by using the RSM, optimized the fluid velocity and heat transfer passing from the stretching sheet. By increasing the Prandtl number, the convection heat transfer by 43% increased the ratio of the minimum Prandtl number. By balanced modes for Prandtl number and viscoelastic parameter and wall temperature, the best optimization occurred for fluid velocity and fluid temperature with f = 0.67 and θ = 0.606. The results of the Variation Iteration method are accurate for the nonlinear solution. As the value of k increases, the value of fluid velocity increased and by increasing the Prandtl number, the value of temperature decreases.

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“…In this paragraph other nonlinear models is discussed to know the importance of nonlinear problems in real life. Ibrahim et al [24] uses the Kellar box approach to discuss the effects of viscous dissipation, melting over a stretching sheet, a chemical reaction on williamson and maxwell nanofluids. Ajibade et al [25] used the DTM approach to study suction and injection on a vertical channel.…”

Section: Introductionmentioning

confidence: 99%

Time-Periodic Thermal Boundary Effects on Porous Media Saturated with Nanofluids: CGLE Model for Oscillatory Mode

Kiran

Manjula

2022

Advances in Materials Science

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The stability of nonlinear nanofluid convection is examined using the complex matrix differential operator theory. With the help of finite amplitude analysis, nonlinear convection in a porous medium is investigated that has been saturated with nanofluid and subjected to thermal modulation. The complex Ginzburg-Landau equation (CGLE) is used to determine the finite amplitude convection in order to evaluate heat and mass transfer. The small amplitude of convection is considered to determine heat and mass transfer through the porous medium. Thermal modulation of the system is predicted to change sinusoidally over time, as shown at the boundary. Three distinct modulations IPM, OPM, and LBMOhave been investigated and found that OPM and LBMO cases are used to regulate heat and mass transfer. Further, it is found that modulation frequency (ω f varying from 2 to 70) reduces heat and mass transfer while modulation amplitude (δ 1 varying from 0.1 to 0.5 ) enhances both.

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Melting and viscous dissipation effect on upper‐convected Maxwell and Williamson nanofluid

Cited by 14 publications

References 36 publications

Critical points and stability analysis in MHD radiative non‐Newtonian nanoliquid transport phenomena with artificial neural network prediction

Critical points and stability analysis in MHD radiative non‐Newtonian nanoliquid transport phenomena with artificial neural network prediction

Examination of warm transfer on extending sheet by variation iteration method strategy and investigation of arrangements for optimizing liquid properties

Time-Periodic Thermal Boundary Effects on Porous Media Saturated with Nanofluids: CGLE Model for Oscillatory Mode

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