Numerical investigation of the magnetohydrodynamic hybrid nanofluid flow over a stretching surface with mixed convection: A case of strong suction

The present work explores the physical aspects of the alumina and silver nanoparticles on the magnetohydrodynamic (MHD) flow of mixed convection micropolar hybrid nanofluid with ethylene glycol + water ( EG - H 2 O ) base fluid via stretching surface embedded in a porous medium. A strong magnetic field is employed normally in the flow direction. The behavior of the suction on the presented flow analysis is discussed strongly. Heat transport phenomena are analyzed. The current model's mathematical modeling is based on higher-order nonlinear partial differential equations, which are then translated into higher-order nonlinear ordinary differential equations using appropriate similarity transformations. The modeled higher-order nonlinear ordinary differential equations are solved using NDSolve technique. The physical significance of the different flow parameters on the velocity, microrotation, and temperature profiles of the hybrid nanofluid are described in a graphical form. In a tabular form, the skin friction coefficients for nanofluid and hybrid nanofluid against various flow parameters are calculated. Some important results from this investigation are demonstrated that the velocity of the hybrid nanofluid is higher for the stretching ratio parameter and it is detected that the suction parameter enhanced the microrotation profile of the hybrid nanofluid. From the comparison, it is noted that the velocity, microrotation, and temperature of the hybrid nanofluid are higher as compared to the velocity, microrotation, and temperature of the alumina nanofluid and silver-nanofluid.

Automated summary

The physical aspects of the alumina and silver nanoparticles on the magnetohydrodynamic (MHD) flow of mixed convection micropolar hybrid nanofluid with EG-H2O base fluid via stretching surface embedded in a porous medium are investigated and analyzed. The influence of suction on the flow behavior is discussed, along with the analysis of heat transport phenomena. Nonlinear partial differential equations are transformed into nonlinear ordinary differential equations and solved using the NDSolve technique. The influence of different flow parameters on velocity, microrotation, and temperature profiles of the hybrid nanofluid is depicted graphically, and the skin friction coefficients for nanofluid and hybrid nanofluid are calculated and presented in tabular form. Results show that the velocity of the hybrid nanofluid is higher with increasing stretching ratio parameter, and the suction parameter enhances the microrotation profile of the hybrid nanofluid. Furthermore, the velocity, microrotation, and temperature of the hybrid nanofluid are found to be higher compared to the alumina nanofluid and silver-nanofluid.