Abstract
In this study, the (Cu, Ag) hybrid nanomaterials model is implemented in blood flow equations to investigate its effects on the flow patterns. An analysis for thermal transport is also performed through the melting heat transfer phenomenon. The effects of thermal radiation with Ohmic and viscous dissipation are also considered to explore in heat transport mechanism. Such formulations are going to produced PDEs by combining physical phenomenon through a permeable porous surface. Then, the governing equations are handled using the appropriate similarity transformations to obtain the coupled differential equations system, which is then numerically solved through the bvp4c scheme for dual solutions. The effects of various controlling parameters on fluid velocity and temperature distribution, as well as skin friction coefficient and heat transportation rate, are graphically depicted. According to the obtained findings, in comparison to the nanofluid, the velocity and heat transfer of the hybrid nanofluid model have significant impacts. This study reveals that the performance of the hybrid-nanofluid is more significant to that of the regular nanofluid. In limiting cases, the current results are also compared to those of the previous studies.
NSTL