Comprehensive Examination of the Three-Dimensional Rotating Flow of a Ucm Nanoliquid Over an Exponentially Stretchable Convective Surface Utilizing the Optimal Homotopy Analysis Method

Vaidya, Hanumesh; Prasad, K. V.; Makinde, Oluwole Daniel; Vajravelu, K.; Wakif, Abderrahim; Basha, Hussain

doi:10.5098/hmt.14.11

Cited by 4 publications

(5 citation statements)

References 26 publications

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“…The numerical analysis has performed for heat transfer of Cu-water Nano-fluid in an enclosure circular cylinder in the presence of a magnetic field (horizontal) by Sheikholeslami et al [18]. Nevertheless, many authors have published several recent numerical and analytical articles on the demonstrating of natural convection heat and mass transfer in NLs of various physical phenomena, those are as follows, Kandasamy et al [19], Ghosh and Mukhopadhya [20], Vaidya et al [21], and Prasad et al [22][23], Shamshuddin et al [24][25][26].…”

Section: Introductionmentioning

confidence: 99%

“…The main aim and objective to inspect the 3D MHD Jeffery NLs flow over a bidirectional exponential stretching surface/sheet with Soret and Dufour effect, rate of first-order chemical reaction, convective boundary condition, slip velocities, and mass flux tiny-sized concentration zero had not been investigated. A significant examination is being accomplished about the analytical solution through the Optimal Homotopy Analysis Method (OHAM, see details Vaidya et al [21], Prasad et al [22][23]) very few investigators attempted to tackle the NLs problem with the novel analytical method. The figures, and graphs are plotted and tables are erected to exhibit the outcomes of suitable aspects on fluid flowing, energy, heat, and mass transport rate.…”

Section: Introductionmentioning

confidence: 99%

“…[21], Prasad et al. [22–23]) very few investigators attempted to tackle the NLs problem with the novel analytical method. The figures, and graphs are plotted and tables are erected to exhibit the outcomes of suitable aspects on fluid flowing, energy, heat, and mass transport rate.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Heat and Mass transport phenomenon on 3D MHD Jeffery Nano‐liquid past an exponentially stretchable sheet subject to Soret and Dufour effect: Optimal Solutions

Basha

2024

Z Angew Math Mech

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The literature survey reveals that nano‐liquids are more efficient for heat and mass transport in association with liquids traditionally. However, insight into established techniques for enhancing heat and mass transport in nano‐materials have filled the gaps. Subsequently, extensive research on the aforementioned model has become dynamic. The present investigation aims to study Magnetohydrodynamics on three‐dimensional incompressible, non‐Newtonian Jeffrey nano‐fluid flow over a bidirectional stretchable surface with slip velocities, convective, and mass fluxed zero conditions. Additionally, the impact of Soret and Dufour effects, along with the rate of the first‐order chemically reacted parameter, are taken into consideration. The dimensional equations are transformed into non‐dimensional ones by adopting the Optimal Homotopy Analysis Method (OHAM) to solve highly coupled non‐linear equations semi‐analytically. The results are represented graphically and listed numerically. The current research reveals a significant finding, the higher Deborah numbers amplify the horizontal velocity gradient, while reducing the Jeffery fluid parameter has a similar effect. Moreover, both the Jeffery fluid parameter and Deborah number contribute to the increase in thermal boundary layer thickness, which contrasts with the gradient of nano‐particle concentration. The obtained results are compared with the non‐availability of literature in the same direction by assuming some special cases on different gradients.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Heat and Mass transport phenomenon on 3D MHD Jeffery Nano‐liquid past an exponentially stretchable sheet subject to Soret and Dufour effect: Optimal Solutions

Basha

2024

Z Angew Math Mech

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“…Vaidya et al [39] studied mixed convective nanofluid flow over a nonlinearly stretched riga plate. Prasad et al [20] examined three-dimensional rotating flow of nano-liquid over an exponentially stretchable convective surface. Sreedevi et al [35] discussed the joint effects of Soret and Dufour on MHD flow with heat and mass transfer past a permeable stretching sheet in presence of thermal radiation.…”

Section: Introductionmentioning

confidence: 99%

Double diffusive effects on nanofluid flow toward a permeable stretching surface in presence of Thermophoresis and Brownian motion effects: A numerical study

Deepthi,

Narla,

Srinivasa Raju

2024

Numerical Methods Partial

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The present study explores the nanofluid boundary layer flow over a stretching sheet with the combined influence of the double diffusive effects of thermophoresis and Brownian motion effects. For the purpose of transforming nonlinear partial differential equations into the linear united ordinary differential equation method, the similarity transformation technique is used. The Runge–Kutta–Fehlberg method was used to solve the equations of flow, along with sufficient boundary conditions. The effect on hydrodynamic, thermal and solutes boundary layers of a number of related parameters is investigated and the effects are graphically displayed. In conclusion, a strong agreement between the current numerical findings and the previous literature results is sought.

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“…In a channel with active heaters and coolers, a numerical simulation was introduced by Ma et al [37] to examine the impacts of magnetic field on heat transfer in a MgO − Ag − H 2 O nanoliquid. Prasad et al [38] examined the upper-convected Maxwell three-dimensional rotational flow with a convective boundary condition and zero mass flux for the concentration of nanoparticles. Frictional heating is the conversion of fluid kinetic energy to heat due to the frictional forces between all the neighboring fluid layers.…”

Section: Introductionmentioning

confidence: 99%

Entropy Generation in a Dissipative Nanofluid Flow under the Influence of Magnetic Dissipation and Transpiration

Afridi

Allauddin

et al. 2020

Energies

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The present study explores the entropy generation, flow, and heat transfer characteristics of a dissipative nanofluid in the presence of transpiration effects at the boundary. The non-isothermal boundary conditions are taken into consideration to guarantee self-similar solutions. The electrically conducting nanofluid flow is influenced by a magnetic field of constant strength. The ultrafine particles (nanoparticles of Fe3O4/CuO) are dispersed in the technological fluid water (H2O). Both the base fluid and the nanofluid have the same bulk velocity and are assumed to be in thermal equilibrium. Tiwari and Dass’s idea is used for the mathematical modeling of the problem. Furthermore, the ultrafine particles are supposed to be spherical, and Maxwell Garnett’s model is used for the effective thermal conductivity of the nanofluid. Closed-form solutions are derived for boundary layer momentum and energy equations. These solutions are then utilized to access the entropy generation and the irreversibility parameter. The relative importance of different sources of entropy generation in the boundary layer is discussed through various graphs. The effects of space free physical parameters such as mass suction parameter (S), viscous dissipation parameter (Ec), magnetic heating parameter (M), and solid volume fraction (ϕ) of the ultrafine particles on the velocity, Bejan number, temperature, and entropy generation are elaborated through various graphs. It is found that the parabolic wall temperature facilitates similarity transformations so that self-similar equations can be achieved in the presence of viscous dissipation. It is observed that the entropy generation number is an increasing function of the Eckert number and solid volume fraction. The entropy production rate in the Fe3O4−H2O nanofluid is higher than that in the CuO−H2O nanofluid under the same circumstances.

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Comprehensive Examination of the Three-Dimensional Rotating Flow of a Ucm Nanoliquid Over an Exponentially Stretchable Convective Surface Utilizing the Optimal Homotopy Analysis Method

Cited by 4 publications

References 26 publications

Heat and Mass transport phenomenon on 3D MHD Jeffery Nano‐liquid past an exponentially stretchable sheet subject to Soret and Dufour effect: Optimal Solutions

Heat and Mass transport phenomenon on 3D MHD Jeffery Nano‐liquid past an exponentially stretchable sheet subject to Soret and Dufour effect: Optimal Solutions

Double diffusive effects on nanofluid flow toward a permeable stretching surface in presence of Thermophoresis and Brownian motion effects: A numerical study

Entropy Generation in a Dissipative Nanofluid Flow under the Influence of Magnetic Dissipation and Transpiration

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