A theoretical investigation of the MHD water-based hybrid nanofluid flow over a convectively heated rotating disk surface with velocity slips and zero mass flux conditions

In the present model, we have studied the water-based hybrid nanofluid flow through a revolving disk. The slip and convective constraints at boundary are carried out in the problem. In the model, aluminum Al2O3 and copper Cu nanoparticles are taken into consideration to form a hybrid nanofluid with base fluid water. An appropriate set of similarity variables are taken into consideration to transform the PDEs into ODEs. The solution to the model has been gained by taking the HAM procedure. The convergence solution of the model is presented in the Figures’ form. The role of distinct factors in velocities, thermal, and mass concentration sketches are delineated via Figures and Tables. The consequences reveal that the flow profile decelerate with magnetic factor. The skin friction and Nusselt number mounted with mounting in volume fraction. The thermal and concentration distribution rises with escalating thermophoresis factor. An increasing behavior is detected in the temperature distribution with mounting in the heat source factor. The result shows that the variation in hybrid nanofluid is more than nanofluid.