MHD Eyring–Powell nanofluid flow across a wedge with convective and thermal radiation

In this research, a theoretical investigation into the heat transport characteristics of an Eyring–Powell nanomaterial boundary layer flow on wedge surface with passively controlled nanoparticles is carried out. model, thermal convective conditions, radiation, production, and absorption are also studied. The non-Newtonian fluid’s features predicted using model under consideration. Buongiorno used to study how temperature gradient affects thermophoresis affect Brownian motion. prevailing nonlinear equations derived then renewed in ordinary differential value problem (ODBVP) by substituting apt similarity transformations. acquired ODBVP resolved bvp4c method explore fields nanofluid velocity, temperature, nanoparticle concentration. A mathematical examination drag force coefficients Nusselt number out various physical parameters. fluid parameter ( K1) reduces thickness momentum thickness. aspect id="m2">(Nt) enhances field solutal field. id="m3">NuRex−0.5 ) need for stronger internal source mechanism.