Impact of slip boundary conditions, magnetic force, and porous medium on blood flow of Jeffrey fluid

In this study, the comparative study of the peristaltic flow of Newtonian and non-Newtonian fluids under the consideration of the magnetic field in the porous inclined channel is investigated. The effects of velocity slip and convective boundary conditions are also considered. Moreover, the variable liquid properties are also taken. The mathematical model is developed with the help of the Jeffrey fluid model in the form of partial differential equations. After that, convert them into dimensional form by using the dimensionless quantities. The resultant system of equations is solved through the perturbation method and presented the solution of velocity, temperature, and concentration in analytical form. The impact of physical parameters on the velocity, temperature, and concentration profiles are highlighted with the help of the graphs. The outcomes revealed that the magnetic parameter slows down the velocity of the fluid while the Darcy number enhanced the velocity and temperature distribution and suppressed the concentration profile.

Automated summary

This study investigates the comparative study of Newtonian and non-Newtonian fluids in peristaltic flow under the consideration of magnetic field in the porous inclined channel. Velocity slip, convective boundary conditions, and variable liquid properties are also taken into account. The mathematical model is developed using the Jeffrey fluid model and solved through the perturbation method. The results highlight the effects of physical parameters on velocity, temperature, and concentration profiles.