JEFFREY NANOFLUID PERISTALSIS IN VERTICAL CHANNELS: A FRAMEWORK FOR BIOMEDICAL TRANSPORT SYSTEMS

The purpose of this study, which is inspired by earlier research, is to investigate the impact of suction and injection on the peristalsis pumping of a Jeffrey nanofluid in a vertical channel. The governing equations are developed and analytically solved in this study under the conditions of a low Reynolds number and long wavelength. Expressions are produced for the following quantities: velocity profile, pressure rise per wavelength, temperature distribution, and nanoparticles volume fraction. To visually examine the influence of all physical variables on concentration fields, temperature distribution, velocity, pressure rates, frictional force, streamline, and pressure gradient, we utilize the Wolfram MATHEMATICA tool. It is explored how the temperature of the Jeffrey nanofluid and the volume fraction of nanoparticles are affected by thermophoresis parameters and Brownian motion parameters. It is intended to emphasize the importance of suction and injection on the peristalsis of a Jeffrey nanofluid in a vertical layer. This mathematical model can be used effectively to transport cervical cancer in the tiny blood channels of the cervix. It may be necessary to make considerable revisions to address the issue of internal fluid motion in a nonpregnant uterus brought on by myometrial contractions that resemble peristaltic fluid movement and can occur in both symmetrical and asymmetric directions. This is the first study, to the best of the author’s knowledge, no research has been done into how suction and injection affect the peristalsis pumping of a Jeffrey nanofluid in a vertical channel.

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