Abstract
The augmented thermal conductivity is significant in betterment of heat transfer behavior of fluids. A number of other physical quantities such as density, viscosity, and specific heat play the key role in fluid flow behavior. Investigators have shown that the nanofluids have not only superior heat conductivity but also have better convective heat transfer capability than the base fluids. In this article, the analysis of three-dimensional Williamson fluid has been carried out under investigation. The fluid flow is taken over a linear porous stretching sheet under the influence of thermal radiation. The transformed system of equations has been solved by homotopy analysis method. The impact of embedded parameters on the fluid flow has shown graphically. The velocity profile in x-direction is decreased with the augmented stretching, Williamson, coefficient of inertia, and porosity parameters. The velocity profile in y-direction is increased with the enlarged stretching parameter, while reduced with the augmented Williamson, coefficient of inertia, and porosity parameters. The temperature profile is increased with the enlarged stretching, radiation, thermophoresis, parameter and Brownian motion parameters, and Biot number while decreased with the increased Prandtl number. The concentration profile is increased with the increased thermophoresis parameter and Biot numbers, while decreased with the enlarged stretching and Brownian motion parameters.
Highlights
There are abundant applications of non-Newtonian fluid in the field of geophysics, biological sciences, chemical industries, petroleum industries, and so on
The three-dimensional Williamson fluid flow has been examined in this research article
The velocity profile in x-direction is decreased with the augmented stretching, Williamson, porosity, and inertial coefficient parameters
Summary
There are abundant applications of non-Newtonian fluid in the field of geophysics, biological sciences, chemical industries, petroleum industries, and so on Such flows appear in polymer processing, biological fluids, plastic manufacturing, food processing, ice and magma flows. The two-dimensional flow of Williamson fluid under low Reynolds number and long wavelength has been studied by Nadeem and Akram.[4] Pop and Na5 examined the incompressible micro polar fluid flow over a stretching sheet. The effect of thermal radiation on the fluid flow over vertically porous stretched surface has been analyzed by Mukhopadyay.[10] The change in concentration and mass transfer rates of the fluid flow over a horizontal stretched sheet has been numerically investigated by Shateyi and Motsa.[11] The influence of thermaldiffusion and diffusion-thermo on three-dimensional
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