Dynamics of reversals and condensates in 2D Kolmogorov flows

Abstract

We present direct numerical simulations of the different two-dimensional flow regimes generated by a constant spatially periodic forcing balanced by viscous dissipation and large scale drag with a dimensionless damping rate 1/Rh. The linear response to the forcing is a 6×6 square array of counter-rotating vortices, which is stable when the Reynolds number Re or Rh are small. After identifying the sequence of bifurcations that lead to a spatially and temporally chaotic regime of the flow when Re and Rh are increased, we study the transitions between the different turbulent regimes observed for large Re by varying Rh. A large scale circulation at the box size (the condensate state) is the dominant mode in the limit of vanishing large scale drag (Rh large). When Rh is decreased, the condensate becomes unstable and a regime with random reversals between two large scale circulations of opposite signs is generated. It involves a bimodal probability density function of the large scale velocity that continuously bifurcates to a Gaussian distribution when Rh is decreased further.