Affiliation:
1. School of Computer Engineering and Mathematical Sciences, Defence Institute of Advanced Technology, Pune 411025, Maharashtra, India,
2. Department of Mathematics and Statistics, Indian Institute of Technology Kanpur, Kanpur 208016, Uttar Pradesh, India,
Abstract
Abstract
This study presents a numerical investigation to examine the influence of Soret and Dufour parameters on the double-diffusive convective flow of a hybrid nanofluid within an inverted T-shaped porous enclosure. The thermophysical properties and numerical values of the hybrid nanofluid are adopted from experimentally published data. The mathematical model is formulated based on the generalized Darcy–Brinkmann–Forchheimer equation and subsequently simulated using the penalty finite element method. A parametric study is conducted, encompassing a wide range of parameters for Rayleigh number, Darcy number, porosity value, buoyancy ratio, Lewis number, Soret parameter, and Dufour parameter. The resulting flow patterns, temperature distribution (isotherms), and concentration distribution (isoconcentration plots) provide insights into the fluid flow, heat transfer, and mass transfer phenomena within the physical domain. Furthermore, the heat and mass transfer rates at the heated (concentrated) wall are quantitatively evaluated by the mean Nusselt number and mean Sherwood number, respectively, considering various combinations of flow parameters. As a key finding, it is observed that the smaller value of the Rayleigh number remains insignificant at convective flow of thermal and solute phenomena. Moreover, the higher value of Ra reinforces the convective strength of hybrid nanofluid, and it helps to identify the real impact of each parameter. Thus, at a higher Rayleigh number, it is observed that the increasing value of Darcy number, porosity value, Lewis number, and buoyancy ratio significantly influence the convective flow of heat and solute transport activity, whereas the impact of Soret and Dufour parameters shows a relatively less influence on the heat and mass transfer phenomena.
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12 articles.
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