Abstract
This article investigates unsteady magnetohydrodynamic (MHD) mixed convective and thermally radiative Jeffrey nanofluid flow in view of a vertical stretchable cylinder with radiation absorption and heat; the reservoir was addressed. The mathematical formulation of Jeffrey nanofluid is established based on the theory of boundary layer approximations pioneered by Prandtl. The governing model expressions in partial differential equations (PDEs) form was transformed into dimensionless form via similarity transformation technique. The set of nonlinear nondimensional partial differential equations are solved with the help of the homotopic analysis method. For the purpose of accuracy, the optimizing system parameters, convergence, and stability analysis of the analytical algorithm (CSA) were performed graphically. The velocity, temperature, and concentration flow are studied and shown graphically with the effect of system parameters such as Grashof number, Hartman number, Prandtl number, thermal radiation, Schmidt number, Eckert number, Deborah number, Brownian parameter, heat source parameter, thermophoresis parameter, and stretching parameter. Moreover, the consequence of system parameters on skin friction coefficient, Nusselt number, and Sherwood number is also examined graphically and discussed.
Highlights
Nanotechnology has gained potential consideration of researchers and scientists in recent times because of its fruitful engineering and industrials usages in various manufacturing units
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Summary
Nanotechnology has gained potential consideration of researchers and scientists in recent times because of its fruitful engineering and industrials usages in various manufacturing units. Piswas et al [11,12] have investigated mixed convective Jeffrey nanofluid flow in view of stretchable sheet surface with magnetic field effect and thermal radiation effects numerically by utilizing explicit finite difference method. A numerical model is developed to investigates the influence of magnetohydrodynamics and heat mass transference effects of a Jeffrey fluid past by a stretching surface with chemical reaction, and thermal radiation analysis was analyzed by Narayana et al [20]. A numerical investigation was carried out to examine the Joule heating effect on magneto hydromagnetic flow and heat transfer effects on a Jeffrey fluid in view of a permeable stretching sheet with power-law heat flux and heat source by Babu and Narayana [33]. Hayat et al [38] investigated the consequences of the radiative nature of Jeffrey fluid past through an inclined heated stretching cylindrical sheet
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