English

Transitional channel flow: A minimal stochastic model

Fluid Dynamics 2020-12-18 v1 Pattern Formation and Solitons

Abstract

In line with Pomeau's conjecture about the relevance of directed percolation (DP) to turbulence onset/decay in wall-bounded flows, we propose a minimal stochastic model dedicated to the interpretation of the spatially intermittent regimes observed in channel flow before its return to laminar flow. Numerical simulations show that a regime with bands obliquely drifting in two stream-wise symmetrical directions bifurcates into an asymmetrical regime, before ultimately decaying to laminar flow. The model is expressed in terms of a probabilistic cellular automaton evolving von Neumann neighbourhoods with probabilities educed from a close examination of simulation results. It implements band propagation and the two main local processes: longitudinal splitting involving bands with the same orientation, and transversal splitting giving birth to a daughter band with orientation opposite to that of its mother. The ultimate decay stage observed to display one-dimensional DP properties in a two-dimensional geometry is interpreted as resulting from the irrelevance of lateral spreading in the single-orientation regime. The model also reproduces the bifurcation restoring the symmetry upon variation of the probability attached to transversal splitting, which opens the way to a study of the critical properties of that bifurcation, in analogy with thermodynamic phase transitions.

Keywords

Cite

@article{arxiv.2012.09798,
  title  = {Transitional channel flow: A minimal stochastic model},
  author = {Paul Manneville and Masaki Shimizu},
  journal= {arXiv preprint arXiv:2012.09798},
  year   = {2020}
}

Comments

21 pages, 16 figures. Identical to the published version except for the format and the spelling, here kept British but changed to American by the publisher

R2 v1 2026-06-23T21:03:27.503Z