Soret-Dufour mass transfer effects on radiative chemically dissipative MHD plain convective water nanofluid (Al₂O₃, Cu, Ag, & TiO₂) flow across a temperature-controlled upright cone surface with heat blow/suction

In the current analysis, we delivered a computational approach to the 2D boundary layer heat and mass transfer flow of water-based nanofluids over a vertical cone saturated by porous media with heat generation/absorption, thermal radiation, chemical reactions, the Soret-Dufour number, viscous dissipation, and a magnetic field. The controlling partial differential equations are converted into devoid of dimensions form and numerically dealt with by Crank-Nicolson through an implicit finite difference approach. Specifically, the given parameters, such as volume fraction (phi), MHD-Magnetohydrodynamics (M), Soret/Dufour (Sr-Du), viscous dissipation (epsilon), chemical reaction (lambda), thermal radiation (Rd), and heat blowing/suction (Delta), have an impact on boundary layer flow characteristics (velocity, temperature, concentration, drag coefficient, rate of heat transfer, and mass transfer rate) are thoroughly studied, and the outcomes are visually and tabulated to demonstrate the actual significance of the problem.