Beads, bubbles and drops in microchannels: stability of centred position and equilibrium velocity

Understanding and predicting the dynamics of dispersed micro-objects in microfluidics is crucial in numerous natural, industrial and technological situations. In this paper, we experimentally characterized the equilibrium velocity V and lateral position epsilon of various dispersed micro-objects, such as beads, bubbles and drops, in a cylindrical microchannel over an unprecedentedly wide range of parameters. By varying the dimensionless object size (d is an element of [0.1; 1]), the viscosity ratio (lambda is an element of [10(-2); infinity[), the density ratio (? is an element of [10(-3); 2]), the Reynolds number (Re is an element of [10(-2); 10(2)]) and the capillary number (Ca is an element of [10(-3); 0.3]), we offer an exhaustive parametric study exploring various dynamics from the non-deformable viscous regime to the deformable inertial regime, thus enabling us to highlight the sole and combined roles of inertia and capillary effects on lateral migration. Experiments are compared and agree well with a steady three-dimensional Navier-Stokes model for incompressible two-phase fluids, including the effects of inertia and possible interfacial deformations. This model enables us to propose a correlation for the object velocity V as functions of d, epsilon and lambda, obtained in the Re = Ca = 0 limit, but valid for a larger range of values of Re and Ca delimited by the validity of the linear regime. Next, we present stability maps for the centred position showing that non-deformable objects dominated by inertial effects are only stable if large enough, typically for d > 0.7, whereas deformable objects dominated by capillary effects can be stable for much smaller sizes, provided the viscosity ratio is outside the range 0.7 ? lambda ? 10, in which deformability also plays a destabilizing effect, as for inertia.