English

3D instabilities and negative eddy viscosity in thin-layer flows

Fluid Dynamics 2018-06-04 v1

Abstract

The stability of flows in layers of finite thickness HH is examined against small scale three dimensional (3D) perturbations and large scale two-dimensional (2D) perturbations. The former provide an indication of a forward transfer of energy while the later indicate an inverse transfer and the possibility of an inverse cascade. The analysis is performed using a Floquet-Bloch code that allows to examine the stability of modes with arbitrary large scale separation. For thin layers the 3D perturbations become unstable when the layer thickness HH becomes larger than H>c1(νU/U)1/2=c1URe1/2H > c_1 (\nu \ell_{_U}/U)^{1/2}= c_1 \ell_{_U} Re^{-1/2}, where UU is the rms velocity of the flown, U\ell_{_U} is the correlation length scale of the flow, ν\nu the viscosity and Re=UU/νRe=\ell_{_U} U/\nu is the Reynolds number. At the same time large scale 2D perturbations also become unstable by an eddy viscosity mechanism when Re>c2Re>c_2, where c1,c2c_1,c_2 are order one non-dimensional numbers. These relations define different regions in parameter space where 2D and 3D instabilities can (co-)exist and this allows to construct a stability diagram. Implications of these results for fully turbulent flows that display a change of direction of cascade as HH is varied are discussed.

Keywords

Cite

@article{arxiv.1806.00409,
  title  = {3D instabilities and negative eddy viscosity in thin-layer flows},
  author = {Alexandros Alexakis},
  journal= {arXiv preprint arXiv:1806.00409},
  year   = {2018}
}
R2 v1 2026-06-23T02:16:20.260Z