Unlocking the Potential of Magnetohydrodynamic CNTs Casson Nanofluids in Rotating Channels

Introduction

The field of magnetohydrodynamics (MHD) has revolutionized how we understand and manipulate fluid dynamics in various scientific and industrial applications. In a groundbreaking study, researchers investigated the behavior of single-wall carbon nanotubes (SWCNTs) and multi-wall carbon nanotubes (MWCNTs) in Casson nanofluids under the influence of magnetic and thermal radiation effects between two rotating parallel plates.

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Key Findings of the Study

The study conducted numerical simulations to understand the impact of nanoparticle volume fraction (ϕ), Reynolds number (A1), magnetic parameter (M), rotation parameter (A2), and suction/injection effects (Q) on fluid velocity and temperature profiles.

Highlights:

Thermal Efficiency: MWCNTs exhibited a higher heat transfer rate than SWCNTs due to their increased thermal conductivity.
Magnetic Influence: The Lorentz force generated by the magnetic field caused a decrease in velocity profiles, proving its significant impact on fluid flow.
Rotation Effects: The velocity and temperature profiles were highly influenced by the rotation of the parallel plates.
Suction & Injection: Fluid velocity increased with suction (Q > 0) and decreased with injection (Q < 0), altering the overall heat transfer dynamics.

🔗 Read the full study: https://doi.org/10.29328/journal.jpra.1001002

Broader Implications for Heat Transfer Technologies

The American Society of Mechanical Engineers (ASME) emphasizes the importance of nanofluids in optimizing energy efficiency in heat exchangers and industrial cooling systems. Carbon nanotube-based nanofluids have the potential to enhance cooling in electronics, aerospace, and biomedical applications while improving energy conservation.

Applications of CNT-Based Nanofluids

Medical Industry: Used in cancer treatment, drug delivery, and tissue regeneration.

Energy Sector: Improves solar cell efficiency and cooling systems.

Aerospace & Engineering: Helps in MHD propulsion systems and thermal control of satellites.

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Conclusion & Call to Action

The study highlights the transformative potential of CNT-based Casson nanofluids in various industries, paving the way for future innovations in heat transfer and fluid mechanics. Researchers, engineers, and industry leaders can leverage these findings to enhance efficiency and performance in multiple applications.

What are your thoughts on the role of MHD in modern nanotechnology? Share your views in the comments!

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