Abstract
The dynamics of the nanofluid flow between two plates that are placed parallel to each other is of huge interest due to its numerous applications in different industries. Keeping in view the significance of such flow, investigation of the heat transfer in the Cu-H2O nanofluid is conducted between parallel rotating plates. For more significant results of the study, the squeezing effects are incorporated over the plates that are electrically conducting. The nondimensional flow model is then treated analytically (VPM), and the results are sketched against the preeminent flow parameters. The remarkable heat transfer in the nanofluid is noticed against the Eckert and Prandtl numbers, whereas the Lorentz forces oppose the fluid temperature. Furthermore, the shear stresses at the walls drop and the local heat transfer rate rises due to increasing flow parameters. Finally, to validate the study, a comparison is made with existing available science literature and noted that the presented results are aligned with them.
Highlights
Academic Editor: Gengxin Sun e dynamics of the nanofluid flow between two plates that are placed parallel to each other is of huge interest due to its numerous applications in different industries
For more significant results of the study, the squeezing effects are incorporated over the plates that are electrically conducting. e nondimensional flow model is treated analytically (VPM), and the results are sketched against the preeminent flow parameters. e remarkable heat transfer in the nanofluid is noticed against the Eckert and Prandtl numbers, whereas the Lorentz forces oppose the fluid temperature
Mustafa et al [2] pointed out the flow behavior in fluids squeezed between two plates. e influence of multiple preeminent flow parameters on the fluid temperature and mass transport is decorated via graphs and explained comprehensively
Summary
Academic Editor: Gengxin Sun e dynamics of the nanofluid flow between two plates that are placed parallel to each other is of huge interest due to its numerous applications in different industries. Keeping in view the significance of such flow, investigation of the heat transfer in the Cu-H2O nanofluid is conducted between parallel rotating plates. E influence of multiple preeminent flow parameters on the fluid temperature and mass transport is decorated via graphs and explained comprehensively They found the local thermal performance against ingrained flow parameters. E analysis of magnetized flow regimes by considering the suction/ blowing characteristics is imperative It strengthens roots in civil engineering and industries as well. E analytical investigation of the fluid squeezed between parallel disks with suction/blowing characteristics was perceived in [3]. They analyzed the flow characteristics under varying multiple parameters. Dogonchi et al [15] inspected the temperature behavior in the magnetized nanofluid with radiative heat flux effects
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