Modeling of Nonlinear Variable Viscosity on Peristaltic Transport of Fluid with Slip Boundary Conditions: Application to Bile Flow in Duct

Abstract: The present article deals with variable viscosity on the peristaltic transport of bile in an inclined duct under the action of slip boundary conditions. The wall geometry is described by the sinusoidal wave propagating in the axial direction with different amplitude and with constant speed. The flow of fluid is examined in a wave frame of reference, moving with the velocity of the wave.  Mathematical modeling of the problem includes equations of motion and continuity. The fluid flow is investigated by converti… Show more

“…The change in viscosity μ ( y ) and change in thermal conductivity k ( θ ) is deliberated to be varying exponentially with y and θ as 15,22 :…”

“…This study exposed that the axial velocity increases in near the tapered microchannel walls while the reverse situation is observed in the hub part of the trapped channel. According to the effects of slip boundary conditions, Kumari et al 15 looked into the effects of changing viscosity on the peristaltic transport of bile in an inclined conduit. In this article, a comparison of linear and nonlinear variation of viscosity of bile has been made.…”

Insight into the peristaltic motion through a tapered channel with Newton’s cooling subject to viscous dissipation, Lorentz force, and velocity slip

“…The change in viscosity μ ( y ) and change in thermal conductivity k ( θ ) is deliberated to be varying exponentially with y and θ as 15,22 :…”

“…This study exposed that the axial velocity increases in near the tapered microchannel walls while the reverse situation is observed in the hub part of the trapped channel. According to the effects of slip boundary conditions, Kumari et al 15 looked into the effects of changing viscosity on the peristaltic transport of bile in an inclined conduit. In this article, a comparison of linear and nonlinear variation of viscosity of bile has been made.…”

Insight into the peristaltic motion through a tapered channel with Newton’s cooling subject to viscous dissipation, Lorentz force, and velocity slip