Numerical study of unsteady natural convection of variable-order fractional Jeffrey nanofluid over an oscillating plate in a porous medium involved with magnetic, chemical and heat absorption effects using Chebyshev cardinal functions

. The unsteady natural convection of an incompressible, magnetohydrodynamic (MHD), Jeffrey nanofluid in the vicinity of a vertical oscillating plate in a porous medium is examined. Several involving parameters such as thermal radiation, chemical reaction, Soret effect, thermal diffusion, magnetic fi...

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Bibliographic Details
Published in:European physical journal plus 2019-10, Vol.134 (10), p.535, Article 535
Main Authors: Roohi, R., Heydari, M. H., Sun, H. G.
Format: Article
Language:English
Subjects:
Absorption
Applied and Technical Physics
Atomic
Chebyshev approximation
Chemical reactions
Complex Systems
Condensed Matter Physics
Convection
Fluid flow
Fractional calculus
Free convection
Incompressible flow
Magnetic fields
Mathematical and Computational Physics
Matrix methods
Molecular
Nanofluids
Optical and Plasma Physics
Parameters
Physics
Physics and Astronomy
Porous media
Radiation
Regular Article
Theoretical
Thermal diffusion
Thermal radiation
Velocity distribution
Vertical oscillations
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Summary:. The unsteady natural convection of an incompressible, magnetohydrodynamic (MHD), Jeffrey nanofluid in the vicinity of a vertical oscillating plate in a porous medium is examined. Several involving parameters such as thermal radiation, chemical reaction, Soret effect, thermal diffusion, magnetic field and heat absorption are taken into account. To gain an insight into the behavior of a memory-dependent fluid, the variable-order fractional calculus for heat, mass and concentration equations is implemented, which, to the best of the author's knowledge, has not been tackled by the researchers for the present comprehensive problem. The set of governing equations are reformed to the dimensionless form via invoking appropriate variables. A computational matrix method based on the Chebyshev cardinal functions (CCFs) is given to examine the behavior of the relevant problem. In fact, regarding to the established method, the unknown solutions are expanded by the CCFs. Then, the operational matrix of the variable-order fractional derivative is utilized to transfer the problem into solving an algebraic system of equations. The applicability and accuracy of the suggested method are investigated by solving some test problems. The numerical results confirm the high accuracy of the presented approach. The effect of several parameters such as Grashof, Hartmann, Prandtl, Soret and Schmidt numbers, in addition to oscillation frequency, retardation time, radiation, heat absorption and reaction rate are determined and presented graphically. According to the results, increasing the value of fractional order improves the natural convection mechanism as well as the peak value of the velocity profile.
ISSN:2190-5444
2190-5444
DOI:10.1140/epjp/i2019-12873-9