The parametric computation of nonlinear convection magnetohydrodynamic nanofluid flow with internal heating across a fixed and spinning disk

The heat and mass transition characteristics with nonlinear convection flow through impermeable stationary and porous spinning disks are evaluated in the present analysis. The gyrotactic microorganism and magnetic nanoparticulate have been used in the carrier fluid ethylene glycol and water to synthesized nanofluid. The heat and mass propagation are examined by considering heat absorption/generation, thermal radiation and rate of chemical reaction, respectively. The governing equations are transformed to the system of nonlinear ordinary differential equations all through a similarity context. The basic modeled equations are numerically computed using the parametric continuation method. Physical interest variables are illustrated through tables and figures versus velocity, energy, mass and gyrotactic microorganism profiles. It has been observed that the enhancement in nonlinear convection owing to heat generation and temperature coefficient elevated the wall friction along the radial direction of the gyrating disk. The mass transition rate lessens with the consequences of Schmidt number, while enhancing with the increment of the chemical reaction. The application, such as biomedical imaging, cancer therapy, information storage, wastewater treatment and thermal decomposition of ferric oxide nanoparticles made the present analysis more plausible.