English

Two-layer Thermally Driven Turbulence: Mechanisms for Interface Breakup

Fluid Dynamics 2022-05-24 v2

Abstract

It is commonly accepted that the breakup criteria of drops or bubbles in turbulence is governed by surface tension and inertia. However, also {\it{buoyancy}} can play an important role at breakup. In order to better understand this role, here we numerically study Rayleigh-B\'enard convection for two immiscible fluid layers, in order to identify the effects of buoyancy on interface breakup. We explore the parameter space spanned by the Weber number 5We50005\leq We \leq 5000 (the ratio of inertia to surface tension) and the density ratio between the two fluids 0.001Λ10.001 \leq \Lambda \leq 1, at fixed Rayleigh number Ra=108Ra=10^8 and Prandtl number Pr=1Pr=1. At low WeWe, the interface undulates due to plumes. When WeWe is larger than a critical value, the interface eventually breaks up. Depending on Λ\Lambda, two breakup types are observed: The first type occurs at small Λ1\Lambda \ll 1 (e.g. air-water systems) when local filament thicknesses exceed the Hinze length scale. The second, strikingly different, type occurs at large Λ\Lambda with roughly 0.5<Λ10.5 < \Lambda \le 1 (e.g. oil-water systems): The layers undergo a periodic overturning caused by buoyancy overwhelming surface tension. For both types the breakup criteria can be derived from force balance arguments and show good agreement with the numerical results.

Keywords

Cite

@article{arxiv.2005.05633,
  title  = {Two-layer Thermally Driven Turbulence: Mechanisms for Interface Breakup},
  author = {Hao-Ran Liu and Kai Leong Chong and Qi Wang and Chong Shen Ng and Roberto Verzicco and Detlef Lohse},
  journal= {arXiv preprint arXiv:2005.05633},
  year   = {2022}
}

Comments

13 pages, 7 figures

R2 v1 2026-06-23T15:28:56.243Z