Publications

Abstract : The paper communicates the flow, heat and mass transfer of a hybrid nanofluid (AA7072–AA7075/water) between the parallel plates, by incorporating chemical reactions, activation energy and heat source/sink effects. The governing partial differential equations are upgraded to ordinary differential equations by selecting relevant dimensionless variables and then are numerically resolved. Validation of the problem is confirmed between the present and existing work for the limiting cases and is found to be excellent concord. Moreover, the graphs are displayed to discuss the flow, heat and mass transport, friction drag, rate of heat and mass coefficient behaviour for different implanted parameters. It is noted that larger chemical reaction values minimize the concentration curve, while activation energy has the opposite pattern. Furthermore, upsurge values of heat source/sink parameter improve the rate of heat transport, but solid volume fraction reduces the drag friction. Also it has been discovered that AA7072–AA7075/water is a more efficient liquid than AA7072/water. Moving pistons, chocolate fillers, power transfer and compression are all examples of areas where the current research may be useful.