Bubbles-induced transition to elasto-inertial turbulence (2503.03943v1)

Abstract: Interface-resolved direct numerical simulations are performed to investigate bubble-induced transition from laminar to elasto-inertial turbulent (EIT) state in a pressure-driven viscoelastic square channel flow. The Giesekus model is used to account for the viscoelasticity of the continuous phase while the dispersed phase is Newtonian. Simulations are performed for both single and two-phase flows for a wide range of the Reynolds (Re) and the Weissenberg (Wi) numbers. It is demonstrated that injection of bubbles into a laminar viscoelastic flow introduces streamline curvature that is sufficient to trigger an elastic instability leading to a transition to a fully EIT regime. The temporal turbulent kinetic energy spectrum shows a scaling of -2 for this multiphase EIT regime. It is shown that, once the flow is fully transitioned to a turbulent state by the injection of bubbles, the drag increases for all the cases. It is also observed that bubbles move towards the channel centreline and form a string-shaped alignment pattern in the core region at the lower values of Re=10 and Wi=1. In this regime, the flow exhibits an intermittent behaviour, i.e., there are turbulent like fluctuations in the core region while it is essentially laminar near the wall. Unlike the solid particles, it is found that increasing shear-thinning effect breaks up the alignment of bubbles. Interestingly, the drag remains slightly lower in this intermittent regime than the corresponding laminar state.