Multiple slip effects on MHD nanofluid flow over an inclined, radiative, and chemically reacting stretching sheet by means of FDM

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The flow of magneto-micropolar nanofluid, that is, the composition of TiO 2 nanoparticles in an organic solvent, kerosene, and the normal water past a stretchable surface has been considered. With effectiveness idea on the application in several areas, the Darcy-Forchheimer inertial drag and the second-order velocity slip approach are vital for the current investigation. The influence of viscous, Joule and Darcy dissipations on the energy transfer cannot be neglected due to the interaction of the body forces characterized by magnetic and porosity of the medium. The dissipative heat energy with the heat generation/absorption is useful for the enhancement in the fluid temperature. Due to the complexity of the problem, a numerical solution is implemented using the inbuilt code bvp5c with the help of MATLAB software. The physical properties abide by the characterizing parameters that appeared in the flow profiles are presented via graphs and the computed results for the rate coefficients are also displayed through table both for waterand kerosene-based nanofluids. Finally, the main findings of the results are: the growth in the shear rate coefficient is marked due to the inclusion of second-order slip, and an attenuation in the fluid velocity is rendered with an increase in the volume fraction whereas impact is reversed in the case of nanofluid temperature.

Section: Introductionmentioning

confidence: 99%

Characteristics of Darcy–Forchheimer drag coefficients and velocity slip on the flow of micropolar nanofluid

Mathur

Mishra

Pattnaik³

et al. 2021

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“…Swain et al 4 carried out a numerical study to analyze the influence of slip boundary conditions on the transition of nanoliquid along the stretchable sheet. Barik et al 5 examined the chemically reactive nanofluid past an inclined elongated sheet with slip conditions. Ibrahim and Negera 6 investigated the upper‐convected Maxwell nanoliquid with chemical reaction.…”

Section: Introductionmentioning

confidence: 99%

Significance of exponential space‐based heat source and inclined magnetic field on heat transfer of hybrid nanoliquid with homogeneous–heterogeneous chemical reactions

Al‐Kouz

Swain²,

Mahanthesh

et al. 2021

Many chemical reactive methods, like combustion, catalysis, and biochemical involve homogeneous–heterogeneous chemical reaction (HHCR). The collaboration among the heterogeneous and homogeneous reactions is exceedingly multifarious, including the creation and depletion both within the liquid and catalytic surfaces. Here, we observe the influences of Cu and Al2O3 nanoparticles past an elongating sheet under HHCR. An inclined magnetic field with an acute angle is applied to the direction of the flow. Further, radiative heat, temperature, and exponential space‐based heat source aspects are modifying the thermal equation. The governing nonlinear equations are deciphered by utilizing the Runge–Kutta‐based shooting method. It is found that HHCR reduces the solute layer thickness, whereas the increase in the angle of inclination of applied magnetism thickens momentum layer thickness.

“…Furthermore, Rashidi et al 11 proposed the aforesaid flow pattern with the Navier boundary state and solved the problem employing the DTM-Pade, an approximate analytical technique. Several authors [12][13][14][15][16] have worked on the flow behavior of the nanofluids, imposing the thermophysical model, such as the KKL model and they have used both analytical and numerical techniques for the solution of the transformed model. In particular, they have proposed the homotopy analysis method, finite difference method, and Adomian decomposition method, and so on, in various engineering applications, such as pumps and engines, astrophysics, aerodynamics, nuclear physics, and so on.…”

Section: Introductionmentioning

confidence: 99%

A comparative note on the free convection of micropolar nanofluid due to the interaction of buoyancy and the dissipative heat energy

Pattnaik¹,

Pattnaik²,

Mishra

et al. 2021

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