Behavior of ferromagnetic Fe2SO4 and titanium alloy Ti6Al4v nanoparticles in micropolar fluid flow

The nature of Titanium alloy magnetized nanoparticles in non-Newtonian micropolar fluid flow over moving sheet is executed in this research. The model of heat diffusion initiated by Cattaneo and Christov is employed for energy transfer exploration. The Darcy's formula of porosity is employed for the modeling of porous medium term in momentum expression. Further, the non-linear thermal radiation behavior is accounted. Runge-Kutta approach lead to the solutions of nonlinear dimensionless expressions. Solutions of physical phenomenon are plotted by considering distinct values of involving material constraints. The solutions corresponding to Fe(2)So(4) and Ti(6)Al(4)v nanoparticles are compared and discussed. We noted that the velocity f ' (eta) against stronger magnetic field M is higher in case of Fe(2)So(4)-nanoparticles as comparative to Ti(6)Al(4)v-nanoparticles. Temperature theta(eta) is higher for Fe(2)So(4)-nanoparticles as compared to flow in presence of Ti(6)Al(4)v-nanoparticles by enhancing the values of Biot number.