English

Phase-separation models for swimming enhancement in complex fluids

Biological Physics 2015-06-30 v1 Soft Condensed Matter Fluid Dynamics

Abstract

Swimming cells often have to self-propel through fluids displaying non-Newtonian rheology. While past theoretical work seems to indicate that stresses arising from complex fluids should systematically hinder low-Reynolds number locomotion, experimental observations suggest that locomotion enhancement is possible. In this paper we propose a physical mechanism for locomotion enhancement of microscopic swimmers in a complex fluid. It is based on the fact that micro-structured fluids will generically phase-separate near surfaces, leading to the presence of low-viscosity layers which promote slip and decrease viscous friction near the surface of the swimmer. We use two models to address the consequence of this phase separation: a nonzero apparent slip length for the fluid and then an explicit modeling of the change of viscosity in a thin layer near the swimmer. Considering two canonical setups for low-Reynolds number locomotion, namely the waving locomotion of a two-dimensional sheet and that of a three-dimensional filament, we show that phase-separation systematically increases the locomotion speeds, possibly by orders of magnitude. We close by confronting our predictions with recent experimental results.

Keywords

Cite

@article{arxiv.1506.08286,
  title  = {Phase-separation models for swimming enhancement in complex fluids},
  author = {Yi Man and Eric Lauga},
  journal= {arXiv preprint arXiv:1506.08286},
  year   = {2015}
}
R2 v1 2026-06-22T10:01:22.711Z