Vesicles, closed membranes made of a bilayer of phospholipids, are considered as a biomimetic system for the mechanics of red blood cells. The understanding of their dynamics under flow and their rheology is expected to help the understanding of the behavior of blood flow. We conduct numerical simulations of a suspension of vesicles in two dimensions at a finite concentration in a shear flow imposed by countertranslating rigid bounding walls by using an appropriate Green's function. We study the dynamics of vesicles, their spatial configurations, and their rheology, namely, the effective viscosity ${\eta }_{\mathrm{eff}}$. A key parameter is the viscosity contrast $\lambda$ (the ratio between the viscosity of the encapsulated fluid over that of the suspending fluid). For small enough $\lambda$, vesicles are known to exhibit tank treading (TT), while at higher $\lambda$ they exhibit tumbling (TB). We find that ${\eta }_{\mathrm{eff}}$ decreases in the TT regime, passes a minimum at a critical $\lambda ={\lambda }_c$, and increases in the TB regime. This result confirms previous theoretical and numerical works performed in the extremely dilute regime, pointing to the robustness of the picture even in the presence of hydrodynamic interactions. Our results agree also with very recent numerical simulations performed in three dimensions both in the dilute and more concentrated regime. This points to the fact that dimensionality does not alter the qualitative features of ${\eta }_{\mathrm{eff}}$. However, they disagree with recent simulations in two dimensions. We provide arguments about the possible sources of this disagreement.

• Received 1 August 2013

DOI:https://doi.org/10.1103/PhysRevE.88.062707