Electric field strength on MHD aluminum alloys (AA7075) nanofluid flow

This work concerns with a numerical study on heat transfer by MHD aluminum alloys nanofluid (AA7075-water) flow over a nonlinear wall for extensible compactness of electric field. The steady governing momentum and energy equations are transformed to similarity equations for certain families of the c...

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Veröffentlicht in:	SN applied sciences 2019, Vol.1 (1), p.12, Article 12
Hauptverfasser:	Kandasamy, R., Atikah bt Adnan, Nur, Radiah, Mohd, Kamarulzaki, Mohd
Format:	Artikel
Sprache:	eng
Schlagworte:	Alloys Aluminum Aluminum alloys Aluminum base alloys Applications Applied and Technical Physics Boundary conditions Boundary layer thickness Boundary layers Chemical reactions Chemistry/Food Science Computational Convection Design Earth Sciences Electric field strength Electric fields Engineering Engineering: Mechanical Engineering: Design Environment Fluid flow Free convection Heat conductivity Heat transfer Investigations Magnetic fields Materials Science Metallurgy Momentum Nanofluids Nanoparticles Radiation Research Article Reynolds number Runge-Kutta method Temperature Thermal boundary layer Velocity
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creator	Kandasamy, R. Atikah bt Adnan, Nur Radiah, Mohd Kamarulzaki, Mohd
description	This work concerns with a numerical study on heat transfer by MHD aluminum alloys nanofluid (AA7075-water) flow over a nonlinear wall for extensible compactness of electric field. The steady governing momentum and energy equations are transformed to similarity equations for certain families of the controlling parameters. The transformed equations of momentum and thermal transport are solved by applying Runge–Kutta Fehlberg method with shooting technique. The three classical form of nanoparticle shapes are registered into report, i.e., sphere, cylinder and lamina and the heat transfer by natural convection of AA7075-water was studied. It is observed that the thermal and diffusive boundary layer thickness of AA7075-water is weaker in the presence of electric field, E1 = 0.2 as compared to E1 = 0.0. In the presence of electric field, temperature and concentration of lamina shape AA7075 particles hit a dominant role on AA7075-water nanofluid flow regime.
doi_str_mv	10.1007/s42452-018-0014-y
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subjects	Alloys Aluminum Aluminum alloys Aluminum base alloys Applications Applied and Technical Physics Boundary conditions Boundary layer thickness Boundary layers Chemical reactions Chemistry/Food Science Computational Convection Design Earth Sciences Electric field strength Electric fields Engineering Engineering: Mechanical Engineering: Design Environment Fluid flow Free convection Heat conductivity Heat transfer Investigations Magnetic fields Materials Science Metallurgy Momentum Nanofluids Nanoparticles Radiation Research Article Reynolds number Runge-Kutta method Temperature Thermal boundary layer Velocity
title	Electric field strength on MHD aluminum alloys (AA7075) nanofluid flow
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