Author(s)

Muhammad Ramzan^1*, Saima Riasat²

¹Department of Computer Science, Bahria University, Islamabad, Pakistan.
²Department of Mathematical Science, Fatima Jinnah Women University, Rawalpindi, Pakistan.

The present study examines the thermal distribution of ternary nanofluid flow amid two spinning disks influenced by electric and magnetic fields. Keeping in view the shape of the particles, the electrically conducting ternary nanofluid is analyzed with variable thermophysical features. Three types of nanoparticles namely Copper, Aluminum Oxide, and Graphene with spherical, cylindrical, and platelet shapes are taken respectively and are immersed in a (50-50)% ratio of water and ethylene glycol mixture which acts as a base fluid. The anticipated problem is addressed by employing a reliable and user-friendly numerical bvp4c built-in collocation scheme. This solution is then showcased through illustrations and tables. Strengthening the radiation results in an enhanced heat transfer rate. Radial and azimuthal velocities once rotation of disks is enhanced. The key findings provide a strong theoretical background in photovoltaic cells, solar collectors, radiators, solar water heaters, and many other applications.

Trihybrid Nanofluid Flow, Thermal Stratification, Particle Shapes, Spin-ning Disks

Ramzan, M. and Riasat, S. (2024) Analyzing Thermal Stratification and Nanoparticle Shapes Influence on an EMHD Ternary Nanofluid Flow amidst Two Spinning Disks. Journal of Applied Mathematics and Physics, 12, 3017-3025. doi: 10.4236/jamp.2024.128180.