Ternary Casson hybrid nanofluids in convergent/divergent channel for the application of medication

Abstract

The mathematical analysis of time-independent mobility of a modified blood-based Casson hybrid nanofluid including dissimilar nanomaterials in a convergent/di?vergent channel with stretchable/shrinkable walls is investigated. The cumulative impact of magnetic and electric fields governs the flow of modified hybrid nanofluids. In this study, a mediated hybrid fluid containing three unique nanomaterials (titania oxide, alumina oxide, and silver nanoparticles) is used to evaluate the efficiency of hybrid nanofluids in collaboration with blood as a base fluid. The flow analysis is performed using long-wavelength estimations and creeping processes. Such computational innovation will also be used to investigate the transmission of biofluids from big to smaller arteries and intestines. The homotopy analysis method is used to generate the analytical solutions for a system of non-dimensional boundary value problems. Utilizing MATHEMATICA software, the impacts of model physical parameters on rheological phenomena are visually illustrated. The mathematical model can be used to transmit complex biofluids and control fluid transit by employing electro-kinetic modification technologies. To verify the current findings, a comparable investigation is developed.