Computational role of homogeneous–heterogeneous chemical reactions and a mixed convective ternary hybrid nanofluid in a vertical porous microchannel

• Published in: High temperature materials and processes Vol. 43; no. 1; pp. pp. 811 - 825
• Main Authors: Roja, Ajjanna, Saadeh, Rania, Madhukesh, Javali Kotresh, Shamshuddin, MD, Prasad, Koushik Vijaya, Khan, Umair, Prakash, Chander, Hussain, Syed Modassir
• Format: Journal Article
• Language: English
• Published: Berlin De Gruyter 15.11.2024; Walter de Gruyter GmbH
• Subjects: Absorption; Chemical reactions; Convection; Drag; Flow characteristics; Fluid flow; Grashof number; Heat transfer; Heating systems; homogeneous–heterogeneous reaction; Mass transfer; Microchannels; mixed convection flow; Nanofluids; non-uniform heat source/sink; Nusselt number; Parameters; Physical properties; Runge-Kutta method; ternary hybrid nanofluid; Thermal engineering; vertical microchannel
• ISSN: 2191-0324; 0334-6455; 2191-0324
• DOI: 10.1515/htmp-2024-0057

This article mainly scrutinizes the heat transfer and flow characteristics of a mixed convection ternary hybrid nanofluid in a porous microchannel considering the catalytic chemical reaction and nonuniform heat absorption/generation. Using appropriate similarity transformations, the modeled equations are converted into reduced ones and then solved via the Runge–Kutta–Fehlberg 4th/5th order method. To strengthen this analysis, the convection mechanism has been deployed. The effect of pertinent physical parameters on the fluid motion and thermal field is displayed, including some important engineering variables like the Nusselt number, Sherwood number, and drag force. The novel outcomes display that the flow reduces with porous permeability and nanoparticle volume fraction. The temperature of the nanofluid improves with nonuniform heat absorption/generation. The concentration decreases in the presence of both homogeneous and heterogeneous reaction intensities. The heat transfer rate enhances for the Eckert number, and a similar influence on the mass transfer rate is noticed for homogeneous reaction parameters. Further, the drag force declines for the Grashof number. The outcomes show that, in all cases, the ternary hybrid nanofluid shows a greater impact than the nanofluid. The attained findings represent applications in the era of cooling and heating systems, thermal engineering, and energy production.