Contribution of suction phenomenon and thermal slip effects for radiated hybrid nanoparticles (Al2O3-Cu/H2O) with stability framework

Sumera Dero, T. N. Abdelhameed, Kamel Al-Khaled, Liaquat Ali Lund, Sami Ullah Khan*, Iskander Tlili

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

1 Citation (Scopus)

Abstract

This thermal case pronounced the stability framework for stagnation point flow of magnetized alumina and copper nanoparticles with due exponentially shrinking permeable surface. The thermal stability and enhancement of water base liquid had been taken into account with uniform impulsion of hybrid nanomaterials. The induced flow results via exponentially shrinking permeable surface. The similarity transformation simplifies the mathematical model where governing formulated system for hybrid nanofluid is altered into the nondimensional form. A numerical solver called bvp4c is employed in MATLAB software to aid in the problem-solving process, and dual branches have been found. The significance of pertaining parameters associated to the flow model is inspected in view of thermal properties. The findings show that there are two branches for suction strength (S > Sc) and magnetic strength (M > Mc). The bifurcation values Sc and Mc reduce for the occurrence of dual branches as the solid volume percentages of copper increase. Furthermore, for the upper branch solutions, the skin friction and heat transfer rate rise as øCu increases. The temporal stability analysis determines the stability of the dual branches, and it is discovered that only one of them is stable and physically applicable. The presence of suction parameter effectively controls the thermal transportation phenomenon.

Original languageEnglish
Article number2350147
JournalInternational Journal of Modern Physics B
DOIs
Publication statusAccepted/In press - 2022
Externally publishedYes

Keywords

  • dual branches
  • Hybrid nanofluid
  • stagnation point
  • thermal radiation
  • thermal slip

ASJC Scopus subject areas

  • Statistical and Nonlinear Physics
  • Condensed Matter Physics

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