Scalar transport from deformed drops: the singular role of streamline topology

Abstract

We examine scalar transport from a neutrally buoyant drop, in an ambient planar extensional flow, in the limit of a dominant drop phase resistance. For this interior problem, we consider the effect of drop-deformation-induced change in streamline topology on the transport rate (the Nusselt number Nu). The importance of drop deformation is characterized by the Capillary number (Ca). For a spherical drop (Ca = 0), closed streamlines lead to the ratio Nu/Nu0 increasing with the Peclet number(Pe), from unity to a diffusion-limited plateau value (≈ 4.1); Nu0 here denotes the purely diffusive rate of transport. For any finite Ca, the flow field consists of spiralling streamlines that densely wind around nested tori foliating the deformed drop interior. Nu now increases beyond the aforementioned primary plateau, saturating in a secondary plateau that approaches 23.3 for Ca → 0, Pe Ca → ∞, and appears independent of the drop-to-medium viscosity ratio. Nu/Nu0 exhibits an analogous variation for other planar linear flows, although chaotically wandering streamlines in these cases are expected to lead to a tertiary enhancement regime.