Peristalsis of Nanofluids via an Inclined Asymmetric Channel with Hall Effects and Entropy Generation Analysis

This study deals with the entropy investigation of peristalsis a water–copper nanofluid through an asymmetric inclined channel. The channel is anticipated to be filled uniform permeable medium, constant magnetic field impinging on wall physical effects, such as Hall current, mixed convection, Ohmic heating, and heat generation/annihilation, are also considered. Mathematical modeling from given description formulated while employing “long wavelength, low Reynolds number” approximations. Analytical numerical procedures allow for determination flow behavior in resulting system, results which presented form tables graphs, order facilitate analysis. indicate that growth nanoparticle volume fraction corresponds reduction temperature, generation, velocity, pressure gradient. enhanced Brinkman parameters reduce generation temperature flows, whereas permeability parameter reduces velocity gradient considerably. Furthermore, comparison transfer rates two results, different parameters, indicates these agree well. significance underlying lies fact it analyzes non-Newtonian nanofluid, where rheological characteristics fluid predicted using Carreau-Yasuda model by considering various effects.