Litcius/Paper detail

An empirical mean-field model of symmetry-breaking in a turbulent wake

Jared Callaham, Georgios Rigas, Jean-Christophe Loiseau, Steven L. Brunton

2022Science Advances37 citationsDOIOpen Access PDF

Abstract

Improved turbulence modeling remains a major open problem in mathematical physics. Turbulence is notoriously challenging, in part due to its multiscale nature and the fact that large-scale coherent structures cannot be disentangled from small-scale fluctuations. This closure problem is emblematic of a greater challenge in complex systems, where coarse-graining and statistical mechanics descriptions break down. This work demonstrates an alternative data-driven modeling approach to learn nonlinear models of the coherent structures, approximating turbulent fluctuations as state-dependent stochastic forcing. We demonstrate this approach on a high-Reynolds number turbulent wake experiment, showing that our model reproduces empirical power spectra and probability distributions. The model is interpretable, providing insights into the physical mechanisms underlying the symmetry-breaking behavior in the wake. This work suggests a path toward low-dimensional models of globally unstable turbulent flows from experimental measurements, with broad implications for other multiscale systems.

Topics & Concepts

TurbulenceStatistical physicsWakePhysicsSymmetry breakingNonlinear systemForcing (mathematics)Reynolds numberReynolds stressClosure (psychology)Classical mechanicsScale (ratio)MechanicsQuantum mechanicsAtmospheric sciencesEconomicsMarket economyFluid Dynamics and Turbulent FlowsModel Reduction and Neural NetworksProbabilistic and Robust Engineering Design