Study of Non-Darcy Forchheimer Flow Characteristics in Stagnation Point Boundary Layer of Fe₃O₄–EG/Engine Oil Nanofluid over a Nonlinear Stretching Sheet
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Abstract
A logical and mathematical enquiry has been executed to compare the mathematical information and graphical figures of two unique sorts of nanofluid limit layer stream in a non-Darcy permeable medium with Fe3O4.nanoparticle in the liquid. The ongoing surface is persistently extended under a proper regulation and the base fluids are ethylene glycol and motor oil. A numerical model of the stream has been organized and in the wake of redesigning the non-straight fractional differential conditions into an arrangement of Tribute, it has been tackled both systematically by Differential Change Strategy (DTM) in participation with Pade Approximant and mathematically by Runge-Kutta fourth request shooting procedure. The total of the relations between different stream boundaries with the skin grating and the intensity move pace of two unique liquids have been checked by connection coefficients and the effect of the connection has been confirmed utilizing Fisher's t-Test. One of the most fascinating decisions of the advancement study is that the pace of intensity move rate in the Fe3O4-motor oil nanofluid is just about 83-88% higher than that of Fe3O4-ethylene glycol nanofluid. Likewise the connection between different relevant boundaries with the Nusselt number and the skin rubbing coefficient are profoundly huge and they can be directed by our necessity by controlling these boundaries of the stream.
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