Two-dimensional mixed convection radiative nanofluid
flow along
with the non-Darcy permeable medium across a wavy inclined surface
are observed in the present analysis. The transformation of the plane
surface from the wavy irregular surface is executed via coordinate
alteration. The fluid flow has been evaluated under the outcomes of
heat source, thermal radiation, and chemical reaction rate. The nonlinear
system of partial differential equations is simplified into a class
of dimensionless set of ordinary differential equations (ODEs) through
a similarity framework, where the obtained set of ODEs are further
determined by employing the computational technique parametric continuation
method (PCM) via MATLAB software. The comparative assessment of the
current outcomes with the earlier existing literature studies confirmed
that the present findings are quite reliable, and the PCM technique
is satisfactory. The effect of appropriate dimensionless flow constraints
is studied versus energy, mass, and velocity profiles and listed in
the form of tables and figures. It is perceived that the inclination
angle and wavy surface assist to improve the flow velocity by lowering
the concentration and temperature. The velocity profile enhances with
the variation of the inclination angle of the wavy surface, non-Darcian
term, and wavy surface term. Furthermore, the rising value of Brownian
motion and thermophoresis effect diminishes the heat-transfer rate.