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Capitalization of Hybrid Ferrite nanoparticles along with Multi Walled Carbon Nano Tubes for Enhancement of Thermal Features Generated by Natural Convection in Newtonian Fluid Flow in Cavity
  • S Bilal,
  • Mohsen Sheikholeslami
S Bilal
Air University Islamabad
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Mohsen Sheikholeslami
Department of Mechanical Engineering, Babol Noshirvani University of Technology, Babol, Iran
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Peer review status:UNDER REVIEW

30 May 2020Submitted to Mathematical Methods in the Applied Sciences
12 Jun 2020Assigned to Editor
12 Jun 2020Submission Checks Completed
13 Jun 2020Reviewer(s) Assigned


Present exertion is devoted to manipulate exclusive investigation about enhancement in thermal attributes of usual Newtonian fluid with the inclusion of Hybridized ferrite nanoparticles ( ) along with multi walled carbon nano Tubes (MWCNT). The flow is taken in a square cavity influenced by applied Lorentzian field. Effects of porous medium are envisioned by utilizing Darcy law. Energy aspects in flowing domains are interrogated in the presence of radiative aspects characterized by Roseland approximations. Mathematical modelling representing the key features of flow under sundry aspects is manifested in the form of partial differential system. The attained complex differential expressions are handled by control volume finite element method (CVFEM). Expressions representing key features of ferrite nanoparticles and multi wall carbon nano tubes are exhibited in tabular form. Impact of flow controlling parameters in the form of isotherm and stream lines is revealed. Variation in convective heat transfer against different variables in 3D pictorial view is conducted. Grid independence along with mesh analysis is disclosed for assurance of computed data. Assurance of present results is also executed by comparing it with previous work. It is inferred that thermal flux coefficient enhances by intensifying magnitude of Rayleigh and Darcy parameters. Nusselt number shows decrementing pattern against mounting effect of magnetic field strength. Momentum distribution manifests uplifting behavior against the magnetic field and Darcy parameter.