MM Bhatti
Numerical study of slip and radiative effects on magnetic Fe3O4-water-based nanofluid flow from a nonlinear stretching sheet in porous media with Soret and Dufour diffusion
Bhatti, MM; Khalique, CM; Beg, TA; Beg, OA; Kadir, A
Authors
CM Khalique
TA Beg
Prof Osman Beg O.A.Beg@salford.ac.uk
Professor
Dr Ali Kadir A.Kadir@salford.ac.uk
Associate Professor
Abstract
Increasingly sophisticated techniques are being developed for the manufacture of functional nanomaterials. A growing interest is also developing in magnetic nanofluid coatings which contain magnetite nanoparticles suspended in a base fluid and are responsive to external magnetic fields. These nanomaterials are “smart” and their synthesis features high-temperature environments in which radiative heat transfer is present. Diffusion processes in the extruded nanomaterial sheet also feature Soret and Dufour (cross) diffusion effects. Filtration media are also utilized to control the heat, mass and momentum characteristics of extruded nanomaterials and porous media impedance effects arise. Magnetite nanofluids have also been shown to exhibit hydrodynamic wall slip which can arise due to non-adherence of the nanofluid to the boundary. Motivated by the multi-physical nature of magnetic nanomaterial manufacturing transport phenomena, in this paper, we develop a mathematical model to analyze the collective influence of hydrodynamic slip, radiative heat flux and cross-diffusion effects on transport phenomena in ferric oxide (Fe3O4-water) magnetic nanofluid flow from a nonlinear stretching porous sheet in porous media. Hydrodynamic slip is included. Porous media drag is simulated with the Darcy model. Viscous magnetohydrodynamic theory is used to simulate Lorentzian magnetic drag effects. The Rosseland diffusion flux model is employed for thermal radiative effects. A set of appropriate similarity transformation variables are deployed to convert the original partial differential boundary value problem into an ordinary differential boundary value problem. The numerical solution of the coupled, multi-degree, nonlinear problem is achieved with an efficient shooting technique in MATLAB symbolic software. The physical influences of Hartmann (magnetic) number, Prandtl number, Richardson number, Soret (thermo-diffusive) number, permeability parameter, concentration buoyancy ratio, radiation parameter, Dufour (diffuso-thermal) parameter, momentum slip parameter and Schmidt number on transport characteristics (e.g. velocity, nanoparticle concentration and temperature profiles) are investigated, visualized and presented graphically. Flow deceleration is induced with increasing Hartmann number and wall slip, whereas flow acceleration is generated with greater Richardson number and buoyancy ratio parameter. Temperatures are elevated with increasing Dufour number and radiative parameter. Concentration magnitudes are enhanced with Soret number, whereas they are depleted with greater Schmidt number. Validation of the MATLAB computations with special cases of the general model is included. Further validation with generalized differential quadrature (GDQ) is also included.
Citation
Bhatti, M., Khalique, C., Beg, T., Beg, O., & Kadir, A. (2020). Numerical study of slip and radiative effects on magnetic Fe3O4-water-based nanofluid flow from a nonlinear stretching sheet in porous media with Soret and Dufour diffusion. Modern Physics Letters B, 34(02), 2050026. https://doi.org/10.1142/S0217984920500268
Journal Article Type | Article |
---|---|
Acceptance Date | Sep 9, 2019 |
Online Publication Date | Dec 9, 2019 |
Publication Date | Feb 1, 2020 |
Deposit Date | Sep 18, 2019 |
Publicly Available Date | Dec 9, 2020 |
Journal | Modern Physics Letters B |
Print ISSN | 0217-9849 |
Electronic ISSN | 1793-6640 |
Publisher | World Scientific Publishing |
Volume | 34 |
Issue | 02 |
Pages | 2050026 |
DOI | https://doi.org/10.1142/S0217984920500268 |
Publisher URL | https://doi.org/10.1142/S0217984920500268 |
Related Public URLs | https://www.worldscientific.com/worldscinet/mplb |
Additional Information | Additional Information : Title amended on publication from original 'Numerical study of slip and radiative impact on magnetic FE3O4-water-based nanofluid flow from a nonlinear porous stretching plate with Soret and Dufour diffusion' |
Files
MODERN PHYSICS LETTERS B SORET DUFOUR SLIP iron oxide magnetic nanofluid dynamics SEP 11TH 2019.pdf
(726 Kb)
PDF
You might also like
Simulation of magneto-nano-bioconvective coating flow with blowing and multiple slip effects
(2024)
Journal Article