Impacts of Mass Suction, Magnetic Field and Chemical Reaction On Powell- Eyring Nanofluid Flow

Abubakar Assidiq Hussaini, Umar Aliyu Mujahid, Adamu Abdulkadir Tata, Jaafar Aliyu
Journal of Thermal and Fluid Science
volume 5: Issue 2, July-Dec 2024, pp 1-16

Author's Information
Abubakar Assidiq Hussaini1 
Corresponding Author
1Department of Mathematical Science, Abubakar Tafawa Balewa University, Bauchi, Nigeria.
alhajhabu@gmail.com

Umar Aliyu Mujahid2, Adamu Abdulkadir Tata3, Jaafar Aliyu4
2Department of Statistics, Federal Polytechnic Kaltungo, Gombe, Nigeria.


Adamu Abdulkadir Tata3, Jaafar Aliyu4
3,4Department of Mathematics and Statistics, Federal Polytechnic, Bauchi, Nigeria.

Article -- Peer Reviewed
Published online – 30 Dec 2024

Open Access article under Creative Commons License

Cite this article – Abubakar Assidiq Hussaini, Umar Aliyu Mujahid, Adamu Abdulkadir Tata, Jaafar Aliyu “Impacts of Mass Suction, Magnetic Field and Chemical Reaction On Powell- Eyring Nanofluid Flow ”, Journal of Thermal and Fluid Science, RAME Publishers, vol. 4, issue 2, pp. 1-9, December 2024.
https://doi.org/10.26706/jtfs.5.2.20240902

Abstract:-
within the present research, the researchers investigated at the magnetohydrodynamic (MHD) flow through the boundary layer of Powell-Eyring nanofluid across an irregular stretching material with variable permeability. The researchers investigated a fluid with electrical conductivity alongside a magnetic parameter implemented transversely to its material. The computational equations were generated through a method called boundary layer approximation by employing non-dimensional values. The process of research is subjected to new conventional boundaries constraints that require nil nanoparticle mass flux. Appropriate conversions have been employed for turning all of the partial differential equations towards certain ordinary differential equations. Maple has been employed to deal with the non- linear flow of momentum, temperature, alongside nanoparticle concentration problems. Visual examination of relevant parameters is distributed among graphical depictions along with table values. subsequently, the we discovered that greater quantities of the amount of mass suction parameter enhance both fluid's temperature and concentration profiles while having no effect on the momentum profile. The impacts of the magnetic field parameter showed that the momentum profile dropped while the ambient temperature and nanoparticle concentration curves flipped. Higher values of the permeability parameter improve both the temperature and concentration profiles, nonetheless momentum profile does not improve at all. Chemical reactions have little influence on velocity or temperature, just on nanoparticle concentration profiles.
Index Terms:-
solar; Nano additives; thermal storage; central receiver tube; heat transfer; experimental analysis.
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