4.2 Article

Hybrid nanofluid to enhance heat transfer with velocity and temperature jump impacts

Journal

WAVES IN RANDOM AND COMPLEX MEDIA
Volume -, Issue -, Pages -

Publisher

TAYLOR & FRANCIS LTD
DOI: 10.1080/17455030.2022.2071496

Keywords

Mixed convection; thermal radiation; porous surface; shooting technique bvp4c; MATLAB

Funding

  1. Deanship of Scientific Research at King Khalid University, Abha, Saudi Arabia [RGP.2/184/43]

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This study investigates the heat transfer characteristics of a novel fluid called hybrid nanofluids and finds that incorporating nanomaterials in the fluid can enhance heat transfer efficiency. This has significant implications for heat transfer applications in domestic and manufacturing fields.
Currently, due to the innovative thermal efficiency, a novel fluid class, identified as 'hybrid nanofluids', is being investigated. It has important applications for heat transfer in domestic and manufacturing fields. These fluids have pretty good applications, in transportation, condensers, industry, medical sciences, power plants, etc. Here, we observed the heat transfer of steady magnetic field flow in hybrid nanofluid over the porous surface. We analyze the mixed convection flow by its velocity slip behavior. The impacts of temperature and temperature jumps are considered. The consequence of heat source is also considered. Sodium alginate is used as the base fluid, and alumina and silicon dioxide are used as nanoparticles in the flow problem. The modeled governing system of equations with boundary constraints is transmuted into the ordinary differential equations utilizing the appropriate similarity variables. Furthermore, the set of dimensionless common differential structures is resolved using the shooting technique Bvp4c in MATLAB. The significance of emerging parameters via fluid velocity and thermal field is explored by the graphical behavior. The computational study for different parameters in the current model illustrates that incorporating the hybrid nanomaterials in the fluid results in more extensive heat transfer than that generated by mono-nanofluid.

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