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Effect of hall current on MHD flow of a nanofluid with variable properties due to a rotating disk with viscous dissipation and nonlinear thermal radiation
T. Von Karman, “Classical problem of rotating disk,” Transfer ASME 61, 705 (1939).
M. E. Erdogan, “Unsteady flow of a viscous fluid due to non-coaxial rotations of a disk and a fluid at infinity,” International Journal of Non-Linear Mechanics 32, 285–290 (1997).
M. Sheikholeslami, M. Hatami, and D. D. Ganji, “Nanofluid flow and heat transfer in a rotating system in the presence of a magnetic field,” Journal of Molecular Liquids 190, 112–120 (2014).
M. Turkyilmazoglu, “Nanofluid flow and heat transfer due to a rotating disk,” Computers & Fluids 94, 139–146 (2014).
P. V. S. Narayana, B. Venkateswarlu, and S. Venkataramana, “Thermal radiation and heat source effects on a MHD Nanofluid past a vertical plate in a rotating system with porous medium,” Heat Transfer Asian Research 44, 21101 (2015).
T. Hayat, M. Rashid, M. Imtiaz, and A. Alsaedi, “Magnetohydrodynamic(MHD) flow of Cu-Water nanofluid due to a rotating disk with partial slip,” AIP Advances 5, 067169 (2015).
S. U. S. Choi and J. A. Eastman, “Enhancing thermal conductivity of fluids with nanoparticles,” ASME International Mechanical Engineering Congress and Exposition 66, 99–105 (1995).
D. S. Chauhan and P. Rastogi, “Heat transfer effects on rotating MHD Couette flow in a channel partially filled by a porous medium with hall current,” Journal of Applied Science and Engineering 15(3), 281–290 (2012).
M. Babaelahi, G. Domairry, and A. A. Joneidi, “Viscoelastic MHD flow boundary layer over a stretching surface with viscous and ohmic dissipations,” Meccanica 45, 817–827 (2010).
J. C. Maxwell, “A Treatise on electricity and Magnetism,” second edition, Oxford University press, Cambridge, UK,(1904).
C. H. Chon, K. D. Kim, S. P. Lee, and S. U. S. Choi, “Empirical correlation finding the role of temperature and particle size for nanofluids (Al2O3) thermal conductivity enhancement,” Applied Physics Letters 87, 153107 (2005).
S. V. Ravikanth and K. D. Debendra, “Experimental determination of thermal conductivity of three nanofluids and development of new correlations,” International Journal of Heat and Mass Transfer 52, 4675–4682 (2009).
M. S. Abdel-wahed, E. M. A. Elbashbeshy, and T. G. Emam, “Flow and heat transfer over a moving surface with non-linear velocity and variable thickness in a nanofluid in the presence of Brownian motion,” Applied Mathematics and Computation 254, 49–62 (2015).
M. Turkyilmazoglu, “An effective approach for evaluation of the optimal convergence control parameter in the homotopy analysis method,” Filomat 30(6), 1633–1650 (2016).
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Analysis of the MHD Nanofluid boundary layer flow over a rotating disk with a constant velocity in the presence of hall current and non-linear thermal radiation has been covered in this work. The variation of viscosity and thermal conductivity of the fluid due to temperature and nanoparticles concentration and size is considered. The problem described by a system of P.D.E that converted to a system of ordinary differential equations by the similarity transformation technique, the obtained system solved analytically using Optimal Homotopy Asymptotic Method (OHAM) with association of mathematica program. The velocity profiles and temperature profiles of the boundary layer over the disk are plotted and investigated in details. Moreover, the surface shear stress, rate of heat transfer explained in details.
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