Visualization of stratification based Eyring-Powell material flow capturing nonlinear convection effects

Radiative effect has appealed consideration of investigators since radiative effect has numerous uses in engineering and industry. Specific uses encompass glass production, polymer processing, solar power, gas cooled, satellites, nuclear reactors and space technology. Keeping the above-mentioned practicality in perspective, here nonlinear convected non-Newtonian (Eyring-Powell) material flow subjected to radiative effect is described. Double stratification, chemical reaction and Robin's type condition are accounted for modeling. Boundary-layer idea yields nonlinear governing expressions which are transfigured to ordinary differential equations via transformation procedure. Significant aspects of dimensionless factors are inspected via graphical description. We witnessed lower thermal and solutal fields subjected to stratification factors (thermal and solutal stratification).

Automated summary

The study discusses nonlinear convected non-Newtonian material flow under radiative effect, incorporating double stratification, chemical reaction, and boundary conditions. Nonlinear governing expressions are derived from boundary-layer concept and transformed into ordinary differential equations through a transformation procedure. The significance of dimensionless factors is examined through graphical representation, focusing on the impact of thermal and solutal stratification on lower thermal and solutal fields.