Abstract
This pioneering study aims to integrate a Yamada-Ota nanofluid model into the Casson-Maxwell quadrahybrid nanofluid framework, comprising a blend of (Ag + Cu + Graphene + MoS2) nanoparticles. This investigation explores the endothermic/exothermic reactions, Arrhenius energy and pollutant concentration within the confines of a stretching cylinder, addressing the thermal and solute jump at the boundary. It is significantly conferred that the heat transfer rate in Maxwell quadrahybrid nanofluid is upsurged respectively by up to 6.69% and 5.17%, with the respective preference of Exo and Endothermic chemical reactions, whereas the respective rates of percentage are 3.64% and 1.32% for Casson quadrahybrid nanofluid. Furthermore, as thermos and solute jumps are preferred, the escalated percentage of heat transmission rate at proximity in a Maxwell quadrahybrid nanofluid is about 7.09% and 5.58%, respectively, while the same elevation rates in Casson quadra hybrid nanofluid are 3.91% and 1% respectively, with elevated pollutant parameters further enhancing thermal and pollutant transfer rates.
Published Version
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call