Abstract
The main concern of current investigation is to develop a steady mathematical model for flow and heat transfer of dusty hybrid nanofluid over a stretching sheet. The amended in the energy equations has been executed by indorsing the viscous dissipation expressions. Moreover, the radiation effects are also permitted with help of Rosseland's approximation. In addition, Titanium alloy, ferromagnetic nanoparticles and slip effect are taken in to the account. The consideration of appropriate variables leads to self-similarity expressions. These non-dimensional expressions are treated numerical scheme known as RKF 45th-order technique. To see clear insight of engineering parameters, a detailed graphical workout has been performed. Various substantial quantities like effective Skin friction coefficient and Nusselt number are adequately altered with physical parameters and delineated through various tables. It is recognized that, the reduction in heat transfer in observed in rising values of Pr for both phases. Further, Hybrid nanomaterial flow plays more effective role in heat transportation process as compared to regular nanofluid flow.
•Hybrid nanomaterial flow plays more effective role in heat transportation process as compared to regular nanofluid flow.•Velocity profile for both fluid and dusty phase is scale back for larger values of slip parameter.•Reduction in heat transfer is observed in rising values of Prandtl for both phases.