An optimal analysis for 3D swirling flow of Jeffrey nanoliquid with Arrhenius activation energy and heat generation/absorption effects

Abstract

The main objective of this research article is to elaborate the impact of activation energy on 3D flow of Jeffrey nanofluid subject to rotating frame. Thermophoretic diffusion and an irregular dispersion effects are considered for current analysis. The present work has tremendous applications in cooling agents, food industry, laser technology, fiber optics, making buildings, tunnels, bridges, highways, airports and dams, etc. Nowadays non-Newtonian nanoliquid flow problems in swirling frame of reference have attained enormous recognition among the researchers because of their remarkable utilizations in industrial, engineering and technological areas. Utilizing appropriate variables, PDEs are converted into ordinary ones. Convergent series solutions are obtained by employing optimal homotopic algorithm (OHAM). Impacts of several variables on different distributions are demonstrated graphically. Moreover rate of heat transport is graphically analyzed against distinct physical flow parameters. Our main findings reveals that both velocities exhibit an elevating behavior via higher Deborah number while reversing trend is noted via higher rotation parameter. An increment in Biot number yields stronger temperature. Furthermore rate of heat transport depreciates via greater thermophoresis parameter while an opposite trend is analyzed via greater brownian movement parameter.