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Abstract

This paper investigates the influence of carbon nanotubes to improve heat transmission with Maxwell nanofluids which is suspended in kerosene oil. This mathematical model has been expressed in terms of partial differential equations, which are transformed by using compatible variables into ordinary differential equation's. The result of this model has been attained numerically via RK fourth order with shooting iteration. The results show that with a larger magnetic field, heat transfer increases radiation while decreasing velocity. The combined electrical magnetohydrodynamic effects have the potential to improve fluid flow rates. Moreover, the non-linear radiation case is dominating to the linear case. This theoretical study may be applied in material science, purification technologies, optics and electricity owing to their astonishing possessions, aerospace industry and many more. Especially in aerospace, by way of the aid in plummeting the weight, satellite weight lessening, lightning protection for aircraft and so on.

Keywords

Electrical magnetohydrodynamic carbon nanotube's non-linear thermal radiation Cattaneo-Christov heat diffusion Maxwell nanofluid

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Electrical magnetohydrodynamic flow of kerosene oil based carbon nanotube's Maxwell nanofluid in the presence of non-linear radiation and Cattaneo-Christov heat diffusion: Applications in aerospace industry

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