Three-dimensional convective rotating hybrid nanofluid flow across the linear stretching / shrinking sheet due to the impact of dissipative heat

The present study investigates the three-dimensional convective rotating hybrid nanofluid flow over a linear stretching/shrinking sheet under the influence of dissipative heat. The behaviour of nanofluids, which are mixtures of Ag and MoS _4 nanoparticles in water in this study, is considered in the occurrence of convective flow and the impact of rotation. The linear stretching / shrinking sheet represents a common model in many industrial processes. The analysis also accounts for the effects of dissipative heat that arise due to viscous dissipation and Ohmic dissipation. A well-equipped set of transformations is used for the conversion of the non-dimensional form of the governing equations. Moreover, the adaptation of the Hamilton–Crosser conductivity model enhances the study due to enhanced physical properties. Further, the combined effect of nanofluid properties, convective flow, rotation and dissipative heat on the fluid flow and heat transportation features is examined followed by the numerical solutions adopted to find the solution of the transformed set of equations. The results obtained from this investigation will have potential implications for enhancing the use of nanofluid in industrial applications where efficient cooling of nuclear reactors, electronics cooling, automotive cooling systems, etc. are crucial. Further, use of nanofluid in optimising heat transfer processes in relevant engineering systems is vital.