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THE IMPRESSION OF INCLINED MAGNETIC FIELD ON MAXWELL FLUID OVER A STRETCHING CYLINDER WITH MELTING HEAT
Keywords:
slip condition, heat source, chemical reaction, melting heat, bvp4cDOI:
https://doi.org/10.17654/0973576324053Abstract
The unique aspects of inclined magnetic field are harnessed across multiple disciplines encompassing diagnostic imaging (MRI), particle acceleration, magnetic levitation (Maglev), magnetic data storage, magnetic sensing and orientation devices. The concept of melting in the context of Maxwell fluid flow is particularly significant in the study of non-Newtonian fluid mechanics. The melting boundary condition helps to optimize the flow and cooling rates, ensuring the quality and uniformity of the final product. Therefore, the present aim is to characterize the impact of inclined magnetization along with heat source and chemical reaction in Maxwell non-Newtonian fluid via a stretching cylinder. A distinctive feature of this research is the adoption of Thompson and Troian slip and melting heat boundary constraint yielding optimized thermal transport. Similarity analysis facilitates the reduction of the governing equations, which are then addressed using bvp4c. Visualizations of physical behavior are provided graphically for key factors, accompanied by validation tables. The velocity undergoes substantial amplification for elevated melting factor. Analysis reveals a negative correlation between magnetic factor, slip factor and velocity.
Received: October 6, 2024
Accepted: November 21, 2024
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