Abstract
We demonstrate through numerical solutions of the Oldroyd-B model in a two-dimensional Taylor–Couette geometry that the onset of elastic turbulence in a viscoelastic fluid can be controlled by imposed shear-rate modulations, one form of active open-loop control. Slow modulations display rich and complex behavior where elastic turbulence is still present, while it vanishes for fast modulations and a laminar response with the Taylor–Couette base flow is recovered. We find that the transition from the laminar to the turbulent state is supercritical and occurs at a critical Deborah number. In the state diagram of both control parameters, Weissenberg versus Deborah number, we identify the region of elastic turbulence. We also quantify the transition by the flow resistance, for which we derive an analytic expression in the laminar regime within the linear Oldroyd-B model. Finally, we provide an approximation for the transition line in the state diagram introducing an effective critical Weissenberg number in comparison to constant shear. Deviations from the numerical result indicate that the physics behind the observed laminar-to-turbulent transition is more complex under time-modulated shear flow.
Highlights
We demonstrate through numerical solutions of the Oldroyd-B model in a two-dimensional Taylor– Couette geometry that the onset of elastic turbulence in a viscoelastic fluid can be controlled by imposed shear-rate modulations, one form of active open-loop control
We have shown an elastic instability towards elastic turbulence at Wi = 10 in earlier work, where we applied a shear rate constant in time in the same geometry[55]
We demonstrate how elastic turbulence is significantly reduced with increasing modulation frequency and vanishes at a critical Deborah number Dec
Summary
We demonstrate through numerical solutions of the Oldroyd-B model in a two-dimensional Taylor– Couette geometry that the onset of elastic turbulence in a viscoelastic fluid can be controlled by imposed shear-rate modulations, one form of active open-loop control. Controlling the flow pattern of viscoelastic fluids is extremely challenging due to their inherent non-linear properties and their strong response to shear d eformations[1,2,3] Viscoelastic fluids, such as polymer solutions, exhibit transitions from steady to time-dependent non-laminar flows, which is useful for heat and mass transport at the micron scale[1,2,4,5,6,7,8,9] whereas in Newtonian fluids transport on such small scales is dominated by diffusion. In this work we report on the rich complex behaviour initiated in viscoelastic flows by applying an active open-loop control scheme in the form of a timemodulated shear rate This method reduces and suppresses elastic turbulence.
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