Transient shear banding during startup flow: Insights from nonlinear simulations

Abstract: We study the dynamics of shear startup of the Johnson-Segalman and non-stretching Rolie-Poly models using nonlinear simulations. We consider cases where the startup is from zero shear rate to shear rates in both the monotonic and nonmonotonic regions of the constitutive curve. For the Johnson-Segalman model, which exhibits a shear stress overshoot during startup, our nonlinear simulations show that transient shear banding is absent regardless of whether the start-up shear rate is in the monotonic or nonmonotonic regions of the constitutive curve. In the latter case, while there is clearly an inhomogeneity en route to the banded state, the extent of shear banding is not substantially large compared to that of the eventual banded state. Marked inhomogeneity in the velocity profile is predicted for the non-stretching Rolie-Poly model only if the solvent to solution viscosity ratio is smaller than O(10^-3, but its occurrence does not appear to have any correlation with the stress overshoot during startup. These inhomogeneities are also very sensitive to initial amplitude of perturbations and the magnitude of Reynolds number. Our nonlinear simulations show that the transient evolution during shear startup is quite sensitive to the Reynolds number when the solvent viscosity parameter is much smaller than unity for non-stretching Rolie-Poly model. However, the results of the Johnson-Segalman model are very robust for solvent to solution viscosity greater than O(10^-3 and do not reveal any transient shear banding during shear startup.