Significance of Quadratic Thermal Radiation on the Bioconvective Flow of Ree-Eyring Fluid through an Inclined Plate with Viscous Dissipation and Chemical Reaction: Non-Fourier Heat Flux Model

Abstract

Ree-Eyring model is a pseudoplastic model, which is beneficial to portray the shear diminishing fluid flows. In this paper, significance of quadratic thermal radiation on the dissipative bioconvective flow of Ree-Eyring nanofluid by an inclined plate with chemical reaction is investigated. Non-Fourier heat flux model is included in the energy equation. Combination of shooting and Runge-Kutta 4th order procedures is utilized to get the preferred outcomes. Features of fluid flow including heat transfer rate are discussed by using correlation coefficient. It is identified that the escalation in Brownian motion parameter leads to the decrement in the fluid concentration, thermophoresis parameter ameliorates the fluid temperature and concentration of microorganisms minifies with larger Schmidt and Peclet numbers. It is observed that the heat transfer rate is consuming a generous positive affiliation with thermal relaxation parameter and the increment in the rate of heat transfer is estimated as 0.00954. It is detected that the skin friction coefficient decreases with the increase in magnetic field parameter and the decrement in skin friction coefficient is estimated as -0.74692. Mass transfer rate increases with the increase in chemical reaction parameter and the increment in mass transfer rate is estimated as 0.14542. Furthermore, Outcomes of this study are compared with earlier results and found to be worthy.