Assisting and Opposing Stagnation Point Pseudoplastic Nano Liquid Flow towards a Flexible Riga Sheet: A Computational Approach

Rehman, Aysha; Hussain, Azad; Nadeem, Sohail

doi:10.1155/2021/6610332

Cited by 20 publications

(12 citation statements)

References 41 publications

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“…According to References [14,22,23], the variation in viscosity is implemented as

\mu (T)={\mu }_{{\rm{\infty }}}[1&#x0002B;{\varepsilon }_{1}({T}_{{\rm{\infty }}}-T)]={\mu }_{{\rm{\infty }}}(1&#x0002B;{\epsilon }_{2}-{\epsilon }_{2}\theta ).

…”

Section: Methodsmentioning

confidence: 99%

“…The finite element simulation for free convective flow in an adiabatic enclosure: study of Lorentz forces and partially thermal walls 21 . The assisting and opposing stagnation point pseudoplastic nanoliquid flow towards a flexible Riga sheet: a computational approach 22 . However, the addition of solid nanoparticles can strengthen the fluids with lower thermal conductivity.…”

Section: Introductionmentioning

confidence: 99%

“…21 The assisting and opposing stagnation point pseudoplastic nanoliquid flow towards a flexible Riga sheet: a computational approach. 22 However, the addition of solid nanoparticles can strengthen the fluids with lower thermal conductivity. In conventional fluids, nanoparticles are made up of metallic or nonmetallic nanometer-size particles.…”

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confidence: 99%

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Entropy generation minimization on electromagnetohydrodynamic radiative Casson nanofluid flow over a melting Riga plate

et al. 2022

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Minimizing entropy generation is a technique that helps improve the effectiveness of real processes by studying the associated irreversibility of system performance of nanofluid. This study examines the entropy generation analysis of electromagnetohydrodynamic radiative Casson flow induced by a stretching Riga plate in a non-Darcian porous medium under the influence of internal energy change, Arrhenius activation energy, chemical reaction, and melting heat transfer. The thermophysical features of the fluid are assumed constant in most of the literature. However, this current research bridges this gap by considering viscosity, conductivity, and diffusivity as temperaturedependent variables. Also, the exponential decaying Grinberg term is used as a resistive force in this investigation due to the electromagnetic properties of the Riga plate in the momentum conservation equation. Some suitable dimensionless variables are introduced to remodel the transport equations into unitless ones and then solved numerically by employing Galerkin Weighted Residual Method. Analyses reveal that the Casson parameter declines the fluid velocity, while the existence of the melting parameter has the

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“…According to References [14,22,23], the variation in viscosity is implemented as

\mu (T)={\mu }_{{\rm{\infty }}}[1&#x0002B;{\varepsilon }_{1}({T}_{{\rm{\infty }}}-T)]={\mu }_{{\rm{\infty }}}(1&#x0002B;{\epsilon }_{2}-{\epsilon }_{2}\theta ).

…”

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Entropy generation minimization on electromagnetohydrodynamic radiative Casson nanofluid flow over a melting Riga plate

et al. 2022

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“…Rehman et al [ 32 ] investigated the flow of pseudoplastic nanoliquids towards a versatile Riga sheet for assisting and opposing stagnation point flow. Hussain et al [ 33 ] developed a computational model for the radiant energy kinetic molecular supposition of fluid-originated nanoparticle fluid in the presence of an induced magnetic force.…”

Section: Introductionmentioning

confidence: 99%

Mass and Heat Transport Assessment and Nanomaterial Liquid Flowing on a Rotating Cone: A Numerical Computing Approach

et al. 2022

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In the present study, we explore the time-dependent convectional flow of a rheological nanofluid over a turning cone with the consolidated impacts of warmth and mass exchange. It has been shown that if the angular velocity at the free stream and the cone’s angular velocity differ inversely as a linear time function, a self-similar solution can be obtained. By applying sufficient approximation to the boundary layer, the managed conditions of movement, temperature, and nanoparticles are improved; afterward, the framework is changed to a non-dimensional framework utilizing proper comparability changes. A numerical solution for the obtained system of governing equations is achieved. The effect of different parameters on the velocity, temperature, and concentration profiles are discussed. Tangential velocity is observed to decrease with an increase in the Deborah number, whereas tangential velocity increases with increasing values of the angular velocity ratio, relaxation to the retardation time ratio, and buoyancy parameter. Expansion in the Prandtl number is noted to decrease the boundary layer temperature and thickness. The temperature is seen to decrease with an expansion in the parameters of lightness, thermophoresis parameter, and Brownian movement. It is discovered that the Nusselt number expands by expanding the lightness parameter and Prandtl number, whereas it increases by decreasing the Deborah number. We also noticed that the Sherwood number falls incrementally in Deborah and Prandtl numbers, but it upsurges with an increase in the buoyancy parameter.

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“…The filtration and mass transfer process, ultrafiltration in the Bowman capsule, fluid reabsorption through renal proximal tubule present in kidney, blood filtration process in artificial kidneys, cooling transpiration, biological fluids, polymeric liquids, and filtration process due to reverse osmosis are examples of such flows. [1][2][3][4][5][6][7][8][9][10][11] It is analyzed through the literature that scientists have tried to solve the hydrodynamic problems in permeable tubes and channels [12][13][14][15] with different reabsorption fluid velocities on the boundary. Marshall et al 16 examined the viscous flow in a uniform channel with permeable boundaries and presumed that the leakage of the fluid is proportional to the pressure change along the channel wall.…”

Section: Introductionmentioning

confidence: 99%

Analytical study of creeping flow of Maxwell fluid in a permeable slit with linear re-absorption

Mehboob

Maqbool

Ramzan

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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This research presents the analytical study of the creeping flow of a Maxwell fluid in a permeable slit under the effect of linear reabsorption. Analysis of fluid leakage on the slit wall is carried out with the help of the law of conservation of momentum in the rectangular coordinates. The mathematical model in the form of the system of nonlinear partial differential equations is solved by the recursive approach explaining the hydrodynamic aspects of creeping Maxwell fluid flow. The expressions for the velocity field, hydrostatic pressure, stream function, leakage flux, and fractional reabsorption on the boundary of the slit are obtained from the mathematical model. Graphical analysis is also established to demonstrate the effects of emerging parameters due to linear reabsorption on slit boundary and relaxation time. It is analyzed that the horizontal and vertical velocity decelerates by the growing values of the relaxation parameter, but the reabsorption rate gives an increasing effect on the shear stress, volume flow rate, and vertical velocity. This analytical study will help the bioengineers in designing the medical tools with the required pressure and flow rate, therefore the application of this model for the hemodialyzer is also important.

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Assisting and Opposing Stagnation Point Pseudoplastic Nano Liquid Flow towards a Flexible Riga Sheet: A Computational Approach

Cited by 20 publications

References 41 publications

Entropy generation minimization on electromagnetohydrodynamic radiative Casson nanofluid flow over a melting Riga plate

Entropy generation minimization on electromagnetohydrodynamic radiative Casson nanofluid flow over a melting Riga plate

Mass and Heat Transport Assessment and Nanomaterial Liquid Flowing on a Rotating Cone: A Numerical Computing Approach

Analytical study of creeping flow of Maxwell fluid in a permeable slit with linear re-absorption

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