Electro-Osmotic Flow of MHD Jeffrey Fluid in a Rotating Microchannel by Peristalsis: Thermal Analysis

In this study, we examine the rotating and heat transfer on the peristaltic and electro-osmatic flow of a Jeffery fluid
in an asymmetric microchannel with slip impact. A pressure gradient and anal axially imposed electric field work
together to impact the electro-osmotic flow (EOF). Mathematical modeling is imported by employing the low Reynolds
number and long wavelength approximation. The exact solution has been simplified for the stream function,
temperature, and velocity distributions. The effects of diverse egress quantities on the gush virtue are exhibited and
discussed with the help of graphs. The shear stress and trapping phenomena have been investigated. The characterization
of results has been resolved for the flow governing ingrained appropriate parameters by employing the table. Our
findings can be summarized as follows: (i) Debye length has a strong influence on the conducting viscous fluid of EOF
in non-uniform micro-channel. (ii) The temperature field is enhanced through the elevated values of the rotation
parameter and EOF. (iii) The shear stress has oscillatory behavior and the heat transmission rate increases with the
magnitude of larger values of EOF. Finally, there is good agreement between the current results and those that have
already been published. This model applies to the study of chemical fraternization/separation procedures and biomicrofluidic
devices for the resolution of diagnosis.