Computation of combined electrical and magnetic field effects on dissipative immiscible newtonian fluid/nanofluid dynamics

Abstract

Newtonian fluid and electromagnetic nanofluid which are not mixing are brimmed in a vertical funnel and are designed to inspect the momentum and energy transfer. The upper and lower faces of the funnel are insulated while the left and right sides of the is heated asymmetrically. The homogeneous Tiwari-Das model is set up to define the nanofluid. The stress conditions are operated at the interface. The balance equations for two fluids are reframed for zero dimension and then numerical solutions are established. The significance of buoyancy force 0≤Gr≤50, viscous dissipation 0≤Br≤1, magnetic 4≤M≤12 and electric field parameters -1≤E≤1, and metallic and carbon-based nanoparticles on the distributions of momentum and heat transfer are explained. Releasing copper oxide, graphit and e oxi aluminumnium oxide in engine oil, water, blood resulted in the appreciable changes in the characteristics of the flow. The presence of magnetic field and nanoparticles scaledown the volumetric flow rate but it is strengthened with the Grashof, Brinkman, and electric field parameters. The obtained results can be used in electromagnetic blood flows, sensing systems, and electromagnetic hybrid fuel cells.