Abstract
A comparative study of radiative Casson and Jeffrey fluids flows generated by the chemically reactive bidirectional stretched sheet is presented. Energy and mass species analysis is performed under radiative heat generation impacts. The Robin’s heat and mass conditions are imposed for the analysis of considered model. The boundary-driven equations are simplified into one independent variable equation by the implication of similarity constraints. The resulted model is tackled by the help of homotopic scheme. The results of various parameters are sketched and interpreted for both Casson and Jeffrey nanofluids. The convergence is expressed through numeric benchmarks and graphical form. The numeric evaluation of Sherwood and Nusselt number is presented against the versatile parametric values. The results showed that the higher velocity curves appeared in Casson nanofluid case as comparative to case of Jeffrey nanofluid. The temperature heat generation constraints boosted the temperature of both Casson and Jeffrey nanofluids. The incrementing trend of chemical reactive and Lewis number resulted weaker concentration profiles for Jeffrey and Casson fluids. The conducted research model has magnificent appliances in solar energy devices, chemical reactors, solar reservoirs, nuclear power plants, heat reservoirs, microwave oven, thermal radiant, thermal imaging and many others.
Published Version
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