English

The vortex-driven dynamics of droplets within droplets

Soft Condensed Matter 2021-01-12 v2 Fluid Dynamics

Abstract

Understanding the fluid-structure interaction is crucial for an optimal design and manufacturing of soft mesoscale materials. Multi-core emulsions are a class of soft fluids assembled from cluster configurations of deformable oil-water double droplets (cores), often employed as building-blocks for the realisation of devices of interest in bio-technology, such as drug-delivery, tissue engineering and regenerative medicine. Here, we study the physics of multi-core emulsions flowing in microfluidic channels and report numerical evidence of a surprisingly rich variety of driven non-equilibrium states (NES), whose formation is caused by a dipolar fluid vortex triggered by the sheared structure of the flow carrier within the microchannel. The observed dynamic regimes range from long-lived NES at low core-area fraction, characterised by a planetary-like motion of the internal drops, to short-lived ones at high core-area fraction, in which a pre-chaotic motion results from multi-body collisions of inner drops, as combined with self-consistent hydrodynamic interactions. The onset of pre-chaotic behavior is marked by transitions of the cores from one vortex to another, a process that we interpret as manifestations of the system to maximize its entropy by filling voids, as they arise dynamically within the capsule.

Keywords

Cite

@article{arxiv.2004.12219,
  title  = {The vortex-driven dynamics of droplets within droplets},
  author = {A. Tiribocchi and A. Montessori and M. Lauricella and F. Bonaccorso and S. Succi and S. Aime and M. Milani and D. A. Weitz},
  journal= {arXiv preprint arXiv:2004.12219},
  year   = {2021}
}

Comments

Post-peer-review version of an article published in Nature Communications. Movies upon request

R2 v1 2026-06-23T15:05:50.278Z