Induced navier's slip with CNTS on a stretching/shrinking sheet under the combined effect of inclined MHD and radiation

The present article investigates viscous fluid flow's heat and mass transfers over a stretching/shrinking sheet using the single and multi-wall carbon nanotube models. The analysis considers the effects of thermal radiation, induced slip, mass transpiration, and inclined magnetic force. The eff...

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Detalles Bibliográficos
Autores: Shettar, M.U. (Mahabaleshwar Ulavathi)|||/items/5cf33f85-ab5a-4a8a-a1db-0c77dbf0b96f, Rudraiah, M. (Mahesh)|||/items/fd1b9178-5ed0-4ff4-9ed7-75328bc5b0c3, Bragard-Monier, J. (Jean)|||/items/180b1150-4828-454b-a19f-8b4ea3b03c0e, Laroze, D. (David)|||/items/3296450a-b959-4b07-802c-9af66189530e
Tipo de recurso: artículo
Fecha de publicación:2023
País:España
Institución:Universidad de Navarra
Repositorio:Dadun. Depósito Académico Digital de la Universidad de Navarra
Idioma:inglés
OAI Identifier:oai:dadun.unav.edu:10171/66064
Acceso en línea:https://hdl.handle.net/10171/66064
Access Level:acceso abierto
Palabra clave:Heat and mass transfer
CNTs
Induced slip
Inclined MHD
Mass transpiration
Radiation
Stretching / Shrinking sheet
Convective heat-transfer
Boundary-layer-flow
Viscous-gas flows
Thermal-radiation
Carbon nanotubes
Shrinking sheet
Fluid
Nanofluids
Velocity
Descripción
Sumario:The present article investigates viscous fluid flow's heat and mass transfers over a stretching/shrinking sheet using the single and multi-wall carbon nanotube models. The analysis considers the effects of thermal radiation, induced slip, mass transpiration, and inclined magnetic force. The effect of the carbon nanotube model on fluid flow has not been considered in previous studies. By exploiting the similarity variable, the governing nonlinear partial differential equations are converted into nonlinear ordinary differential equation. The derived equations are solved analytically, and we obtained an exact solution for the velocity and energy conservation equation. The physical parameters of interest such as induced slip parameter, suction/injection, magnetic field, thermal radiation, and shear stress are analyzed and presented graphically. In particular, we show that the fluid flow in a single wall carbon nanotube transfers more energy than the multivalued nanotubes.