Stability and transitions of the second grade Poiseuille flow

Abstract

In this study we consider the stability and transitions for the Poiseuille flow of a second grade fluid which is a model for non-Newtonian fluids. We restrict our attention to flows in an infinite pipe with circular cross section that are independent of the axial coordinate. We show that unlike the Newtonian (ε=0) case, in the second grade model (ε ≠ 0 case), the time independent base flow exhibits transitions as the Reynolds number R exceeds the critical threshold Rc ≈ 4.124 ε-1/4 where ε is a material constant measuring the relative strength of second order viscous effects compared to inertial effects. At R=Rc, we find that generically the transition is either continuous or catastrophic and a small amplitude, time periodic flow with 3-fold azimuthal symmetry bifurcates. The time period of the bifurcated solution tends to infinity as R tends to Rc. Our numerical calculations suggest that for low ε values, the system prefers a catastrophic transition where the bifurcation is subcritical. We also find that there is a Reynolds number RE with RE < Rc such that for R<RE, the base flow is globally stable and attracts any initial disturbance with at least exponential speed. We show that RE ≈ 12.87 at ε=0 and RE approaches Rc quickly as ε increases.