English

Propulsion driven by self-oscillation via an electrohydrodynamic instability

Soft Condensed Matter 2019-06-10 v1 Biological Physics Fluid Dynamics

Abstract

Oscillations of flagella and cilia play an important role in biology, which motivates the idea of functional mimicry as part of bio-inspired applications. Nevertheless, it still remains challenging to drive their artificial counterparts to oscillate via a steady, homogeneous stimulus. Combining theory and simulations, we demonstrate a strategy to achieve this goal by using an elasto-electro-hydrodynamic instability. In particular, we show that applying a uniform DC electric field can produce self-oscillatory motion of a microrobot composed of a dielectric particle and an elastic filament. Upon tuning the electric field and filament elasticity, the microrobot exhibits three distinct behaviors: a stationary state, undulatory swimming and steady spinning, where the swimming behavior stems from an instability emerging through a Hopf bifurcation. Our results imply the feasibility of engineering self-oscillations by leveraging the elasto-viscous response to control the type of bifurcation and the form of instability. We anticipate that our strategy will be useful in a broad range of applications imitating self-oscillatory natural phenomena and biological processes.

Keywords

Cite

@article{arxiv.1906.03076,
  title  = {Propulsion driven by self-oscillation via an electrohydrodynamic instability},
  author = {Lailai Zhu and Howard A. Stone},
  journal= {arXiv preprint arXiv:1906.03076},
  year   = {2019}
}
R2 v1 2026-06-23T09:46:59.024Z