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Computational Thermal Sciences: An International Journal

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BUOYANCY FORCE AND SLIP CONDITIONS ON HYDROMAGNETIC DISSIPATIVE FLOW OF MICROPOLAR FLUID PASSING AN EXPONENTIALLY STRETCHING SHEET

Volume 14, Issue 1, 2022, pp. 45-60
DOI: 10.1615/ComputThermalScien.2021039005
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ABSTRACT

In this study, the flow of hydromagnetic dissipative micropolar fluid passing an exponentially stretching two-dimensional vertical sheet influenced by buoyancy force, radiation, and slip effects is examined. The dimensional model equations of the flow have been translated from partial into ordinary differential equations via the similarity conversion approach, while the solution to the transmuted equations was found using the shooting technique along with the fourth-order Runge-Kutta scheme. A strong relationship exists between the current results and the related published results found in the literature for limiting situations. Various graphs have been sketched to discuss the impact of the key parameters in relation to the fields of velocity, temperature, and microrotation, while tables are used to identify and explain the influences of some of the controlling parameters on the coefficient of the skin friction and the Nusselt number for both Newtonian and non-Newtonian micropolar fluids. It was noticed that the growth of the velocity slip lowers the fluid motion, while the thermal slip behaves in a similar manner on the temperature field.

Figures

  • The physical flow geometry
  • Effect of the variation of the value of k on the velocity profile
  • Impact of the value of k on the temperature field
  • Microrotation field for K
  • Velocity profiles for α
  • Impact of the value of α on the temperature
  • Effect of the variation of the value of α on microrotation
  • Effect of the value of β on the temperature
  • Effect of the value of λ on microrotation
  • Effect of the variation of the HD number on the velocity profile
  • Temperature profiles for the HD number
  • Microrotation profiles for the HD number
  • Effect of the variation of the value of fw on the velocity field
  • Effect of the value of fw on the temperature
  • Effect of the Ec number on the temperature profile
  • Effect of the variation of the Gr number on the velocity field
  • Impact of the Gr number on the temperature
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CITED BY
  1. Ram M. Sunder, Ashok N., Salawu S.O., Shamshuddin MD., Significance of cross diffusion and uneven heat source/sink on the variable reactive 2D Casson flowing fluid through an infinite plate with heat and Ohmic dissipation, International Journal of Modelling and Simulation, 2022. Crossref

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