Radiated magnetic flow in a suspension of ferrous nanoparticles over a cone with brownian motion and thermophoresis

A theoretical investigation is executed for exploring the flow, heat and mass transfer behavior of magnetohydrodynamic radiated ferrofluid flow caused by a cone in the existence of non-uniform heat source/sink. Dispersion of ferrous nanoparticles finds applications in heat exchanger system, recharge able batteries, chemical catalysts, metallurgy, conducting paints, magnetic recording media, drug delivery, nanofibers, textiles etc. in this study we have used the two types of temperatures namely water (At 10 degrees C and 50 degrees C), having less thermal conductivity as compared with magnetic nanoparticles (CoFe2O4). A simulation is performed by mixing of cobalt ferrous particles in base fluid water with different temperatures. Also, we presented dual solutions for flow over a cone with CoFe2O4+water at 10 degrees C and CoFe2O4+water at 50 degrees C. Governing equations are solved using Runge-Kutta with shooting method and compared with published literature. From the formulated model we found that the friction factor coefficient and rate of heat transfer is more in mixture of CoFe2O4+water at 10 degrees C case compare to CoFe2O4 +water at 50 degrees C case. Similarly the mass transfer rate is more in CoFe2O4 +water at 50 degrees C when compared to CoFe2O4 +water at 10 degrees C case. These results help us to conclude that depending on the industrial appliances we can use heating or cooling processes CoFe2O4 +water at 10 degrees C and CoFe2O4 +water at 10 degrees C fluids respectively.