Computation of radiative Marangoni (thermocapillary) magnetohydrodynamic convection in Cu-water based nanofluid flow from a disk in porous media : smart coating simulation

Abstract

With emerging applications for smart and intelligent coating systems in energy, there has been increasing activity
in researching magnetic nano nanomaterial coating flows. Surface tension features significantly in such regimes,
and in presence of heat transfer, Marangoni (thermocapillary) convection arises. Motivated by elaborating deeper
the intrinsic transport phenomena in such systems, in this paper, a mathematical model is developed for steady
radiative heat transfer and Marangoni magnetohydrodynamic (MHD) flow of Cu-water nanofluid under strong
magnetic field from a disk adjacent to a porous medium. The semi-analytical Adomain Decomposition Method
(ADM) is employed to solve the governing equations which are reduced into ordinary differential equation form
via the Von Karman similarity transformation. Validation with a GDQ (Generalized Differential Quadrature)
algorithm is included. The response in dimensionless velocity, temperature, wall heat transfer rate and shear stress
is investigated for various values of the control parameters. Temperature is reduced with increasing Marangoni
parameter whereas the flow is accelerated. With increasing permeability parameter temperatures are elevated.
Increasing radiative flux boosts temperatures further from the disk surface. Increasing magnetic parameter
strongly damps the boundary layer flow and elevates the temperatures, also eliminating temperature oscillations
at lower magnetic field strengths.