Thermal Performance on Radiative and Ohmic Dissipative Magneto-Nanoliquid Over Moving Flat Porous Plate Suspended by Single Wall Carbon Nanotubes and Multi Wall Carbon Nanotubes

This investigation examines heat transport in the flow of magnetized Blasius flow suspended by carbon nanotubes (CNTs) on an accelerated by moving flat porous plate that contains water and ethylene glycol as base fluids. The transfer of heat has been contemplated in the company of suspended CNTs above a plane plate. The flow simulations are carried by utilizing the impact of magnetic field and uniform porous medium. The transport of thermal is controlled by the significant influence of thermal radiation, heat source, heat and Joule dissipation. Utilizing scaling analysis flow governing problem is converted into a set of higher order nonlinear ordinary differential equations which afterwards are tackled numerically by employing Runge-Kutta Fehlberg 45 method with shooting quadrature. Quantities of flow physical significance are portrayed through graphically. Verification of attained numerical results with available literature under certain limitations are presented and found excellent agreement. With elevation in convective term flow profiles of SWCNTs and MWCNTs are reduced. A reduction of flow characteristic dimensions is observed with increasing magnetic field and porosity terms. Finally, SWCNTs and MWCNTs are positively influenced by Joule dissipation and negatively by thermal radiation.