Abstract
In this study, we investigate the convective flow of a micropolar hybrid nanofluid through a vertical radiating permeable plate in a saturated porous medium. The impact of the presence or absence of the internal heat generation (IHG) in the medium is examined as well as the impacts of the magnetic field and thermal radiation. We apply similarity transformations to the non-dimensionalized equations and render them as a system of non-linear ODEs (Ordinary Differential Equations) subject to appropriate boundary conditions. This system of non-linear ODEs is solved by an adaptive mesh transformation Chebyshev differential quadrature method. The influence of the governing parameters on the temperature, microrotation and velocity is examined. The skin friction coefficient and the Nusselt number are tabulated. We determine that the skin friction coefficient and heat transport rate increase with the increment in the magnetic field. Moreover, the increment in the micropolarity and nanoparticle volume fraction enhances the skin friction coefficient and the Nusselt number. We also conclude that the IHG term improved the flow of the hybrid nanofluid. Finally, our results indicate that employing a hybrid nanofluid increases the heat transfer compared with that in pure water and a nanofluid.
Highlights
The phenomenon of the natural convection process in porous media has become one of the most interesting studies in the last two centuries
The numerical results obtained using the adaptive mesh transformation Chebyshev differential quadrature method (ACDQM) are presented to thisimpact section,ofthe numerical results obtained using the of are presented to studyInthe the magneto-natural convection flow the micropolar hybrid study the impact of the magneto-natural convection flow of the micropolar hybrid nanoliqnanoliquid (Al2 O3 − Cu/water) saturated in a porous medium
This numerical simulation reflected the magneto-natural convection flow of a micropolar hybrid nanoliquid past an orthogonal radiative plate statured in a porous medium
Summary
The phenomenon of the natural convection process in porous media has become one of the most interesting studies in the last two centuries This interest is due to its major application in several industries such as filtration operations, thermal insulation, oceanography, geothermal systems, building insulation, geothermal tanks, geophysics, nuclear flow, metallurgy, cooling of electronic tools and separation operations in chemical industries, for example. Nanofluid is normally utilized to enhance the heat transport rate of the regular fluid. It is a mixed nanosized particle (1–100 nm) that is suspended inside the base fluid.
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