Non -Newtonian Fluid Flow over an Inclined Plate

In this study, we explore the influence of radiation and surface temperature variation on the convective heat transfer of a nanofluid across an inclined plate. Nanoparticle-containing fluids other than water were also explored, including silver, aluminium oxide, and copper. Crank Nicolson, an effective tridiagonal iterative implicit finite difference approach, is used to acquire the solutions. Graphs and tables are used to examine and display the findings for a number of different factors. The findings are in remarkable accord with prior research. An inclined permeable stretching sheet is used to study the momentum, heat, and mass transfer behaviour of an MHD nanofluid flow containing conducting dust particles in the presence of radiation, a nonuniform heat source/sink, a volume fraction of nano particles, a volume fraction of dust particles, and a chemical reaction. We have proposed incorporating conductive dust particles into a Cu-water nanofluid. In order to numerically solve the governing partial differential equations of the flow, heat, and mass transfer, a similarity transformation is used to convert them into nonlinear ordinary differential equations. Using graphs, we illustrate how changes in a few non-dimensional controlling factors may alter the resulting velocity, temperature, and concentration profiles.
Keywords: MHD; Dusty fluid; Nanofluid; Chemical Reaction; Volume fraction; non-uniform heat source/sink