MHD Flow of Thermally Radiative Maxwell Fluid Past a Heated Stretching Sheet with Cattaneo–Christov Dual Diffusion

Loganathan, K.; Alessa, Nazek; Namgyel, Ngawang; Karthik, T.

doi:10.1155/2021/5562667

Cited by 29 publications

(11 citation statements)

References 34 publications

(29 reference statements)

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“…The opposite trend is noticed in the case of higher values of Q . To ensure the accuracy of the results and calculations displayed in Table 1, the results obtained are compared with the results of Mukhopadhyay 38 and Loganathan 20 . Fortunately, validation shows that the results were satisfactory and accurate.…”

Section: Results Analysismentioning

confidence: 99%

“…Chemically reacting Maxwell fluid flow over a convectively heated plate immersed in permeable media in presence of non-linear thermal radiation was reported by Hosseinzadeh et al 18 Mahanthesh et al 19 reported that the nanoparticle-concentration and fluid-temperature profile shows a progressive nature due to solar radiation. Recently, Loganathan et al 20 studied a Maxwell fluid past a stretching surface with Cattaneo–Christov dual diffusion and thermal radiation. They showed that fluid temperature enhanced for the progressive amount of the radiation parameter.…”

Section: Introductionmentioning

confidence: 99%

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Thermally and chemically reacted MHD Maxwell nanofluid flow past an inclined permeable stretching surface

Patil

Patil²,

Humane

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part E:

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The present work deals with chemically reacting unsteady magnetohydrodynamic Maxwell nanofluid flow past an inclined permeable stretching surface embedded in a porous medium with thermal radiation. The formulated governing partial differential equations conveying the flow model of Maxwell with Buongiorno modeled nanofluid is transformed into the system of highly non-linear ordinary differential equations via suitable similarity transformations; those equations are transmuted into an initial value problem and then solved numerically by a shooting approach with Runge–-Kutta fourth-order schema. To obtain the physical insight of the flow situation, the influence of associated parameters on the velocity, temperature, and concentration profiles is sketched graphically with the aid of MATLAB software. Furthermore, engineering quantities of interest are interpreted graphically. The computed numerical results are compared to estimate the validity of the achieved results; it has been found out that the computed results are highly accurate. The impact of the Maxwell parameter and inclination angle of the sheet on the velocity field is observed in decaying. Both thermal and solutal energy transport are progressive in nature as the Maxwell parameter and thermophoresis parameter grows, and a reverse trend is observed for Prandtl number.

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Section: Results Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Thermally and chemically reacted MHD Maxwell nanofluid flow past an inclined permeable stretching surface

Patil

Patil²,

Humane

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part E:

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show abstract

“…Loganathan et al [60] have discussed the significance of Darcy-Forchheimer on third-grade fluid with entropy generation. Loganathan et al [61] have examined Maxwell fluid over a thermally radiative convective sheet. Karthik et al [62] have investigated the importance of zero and non-zero mass fluxes of bioconvection viscoelastic fluid on a three-dimensional Riga plate with swimming microorganisms.…”

Section: Introductionmentioning

confidence: 99%

Insight into the Significance of Viscous Dissipation and Heat Generation/Absorption in Magneto-Hydrodynamic Radiative Casson Fluid Flow With First-Order Chemical Reaction

et al. 2022

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This study is an attempt to explore two-dimensional magneto-hydrodynamic Casson fluid flow with heat generation or absorption, chemical reaction, and viscous dissipation under the effect of thermal radiation. Prescribed surface temperature (PST) and prescribed heat flux (PHF) cases have been taken into account to investigate the problem. The constitutive relations for Casson fluid incorporated with suitable boundary layer approximation theory have been utilized to achieve the flow model equations. The obtained highly non-linear partial differential equations cannot be solved analytically, so we transform them into first-order differential equations, then tackle them with the boundary value problem (BVP-4c) technique in Matlab. Radiation increment decreases primary and secondary velocity profiles abruptly in both cases. Heat generation and absorption augmentation decrease the thermal and momentum boundaries for both studied cases. The skin coefficient for PHF cases has decreased 80% when compared with PST cases. The increment in Casson parameter has enhanced the Nusselt number by 75% for the PST case, whereas the decline in Nusselt number has doubled for the PHF case with the increase in magnetic field. It is concluded that, with the increment in Casson fluid, magnetic, radiation, and permeability parameter the Nusselt number has significantly increased for the PST case. However, for these parameters, an abrupt decline in Nusselt number has been observed for the PHF case. Results reported in this study for shear stress and Sherwood number are in complete agreement with already published previous work.

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“…Loganathan et al [29] utilized a third-grade fluid flow with nanoparticles with zero mass flux and a non-Fourier model to analyze entropy and heat transfer. With the assistance of Cattaneo-Christov dual diffusion, Loganathan et al [30] defined the effect of the hydrodynamic radiative Maxwell fluid model on a hot surface. Jamshed et al [31] investigated radiative Prandtl-Eyring hybrid nanofluid in a parabolic trough surface within a solar water pump to analyze the viscid dissipation, heat generation, and entropy.…”

Section: Introductionmentioning

confidence: 99%

Unsteady Radiative Maxwell Fluid Flow over an Expanding Sheet with Sodium Alginate Water-Based Copper-Graphene Oxide Hybrid Nanomaterial: An Application to Solar Aircraft

Chandrasekaran¹,

Gupta²,

Jangid

et al. 2022

Advances in Materials Science and Engineering

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The primary heat source from the sunlight is solar energy, which is used in photovoltaic panels, solar power plates, photovoltaic streetlights, and solar-based hybrid nanocomposites. A hybrid nanofluid is traversing an expanding sheet in this investigation. Maxwell fluid stream with two nanoparticles is going towards a trough with a parabolic form and is situated within the solar aircraft wing to investigate the phenomena of heat transfer rate. The term solar thermal radiation was introduced to describe heat transfer occurrence. The effectiveness of heat transmission from airplane wings is assessed by taking into account unique phenomena such as magnetic field and heat source. The bvp4c procedure was applied to quantitatively explain the energy and motion equations with MATLAB software. The copper (Cu) and graphene oxide (GO) nanosolid particles are mixed with sodium alginate (SA), a common liquid, to form the nanosolid particles. Numerous control variables are thoroughly examined, including temperature, shear stress, motion, friction component, and Nusselt number. The skin-friction coefficient upsurges with a growing magnetic impression. The upsurge in Deborah number reduces the skin-friction coefficient. The heat source impression declines the heat transport rate but upsurges the skin-friction coefficient. The skin-friction coefficient and heat transport rate increase with growing magnetic impression. When it comes to heat transfer analysis, hybrid nanofluid efficiency is substantially superior to that of regular nanofluid.

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MHD Flow of Thermally Radiative Maxwell Fluid Past a Heated Stretching Sheet with Cattaneo–Christov Dual Diffusion

Cited by 29 publications

References 34 publications

Thermally and chemically reacted MHD Maxwell nanofluid flow past an inclined permeable stretching surface

Thermally and chemically reacted MHD Maxwell nanofluid flow past an inclined permeable stretching surface

Insight into the Significance of Viscous Dissipation and Heat Generation/Absorption in Magneto-Hydrodynamic Radiative Casson Fluid Flow With First-Order Chemical Reaction

Unsteady Radiative Maxwell Fluid Flow over an Expanding Sheet with Sodium Alginate Water-Based Copper-Graphene Oxide Hybrid Nanomaterial: An Application to Solar Aircraft

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