Model the nonlinear instability of wall-bounded shear flows as a rare event: A study on two-dimensional Poiseuille flow
Document Type
Article
Publication Date
5-1-2015
Abstract
In this work, we study the nonlinear instability of two-dimensional (2D) wall-bounded shear flows from the large deviation point of view. The main idea is to consider the Navier-Stokes equations perturbed by small noise in force and then examine the noise-induced transitions between the two coexisting stable solutions due to the subcritical bifurcation. When the amplitude of the noise goes to zero, the Freidlin-Wentzell (F-W) theory of large deviations defines the most probable transition path in the phase space, which is the minimizer of the F-W action functional and characterizes the development of the nonlinear instability subject to small random perturbations. Based on such a transition path we can define a critical Reynolds number for the nonlinear instability in the probabilistic sense. Then the action-based stability theory is applied to study the 2D Poiseuille flow in a short channel.
Publication Source (Journal or Book title)
Nonlinearity
First Page
1409
Last Page
1440
Recommended Citation
Wan, X., Yu, H., & Weinan, E. (2015). Model the nonlinear instability of wall-bounded shear flows as a rare event: A study on two-dimensional Poiseuille flow. Nonlinearity, 28 (5), 1409-1440. https://doi.org/10.1088/0951-7715/28/5/1409