Synchronisation in two-dimensional damped-driven Navier-Stokes turbulence: insights from data assimilation and Lyapunov analysis

Abstract

In Navier--Stokes (NS) turbulence, large-scale turbulent flows inevitably determine small-scale flows. Previous studies using data assimilation with the three-dimensional NS equations indicate that employing observational data resolved down to a specific length scale, 3D, enables the successful reconstruction of small-scale flows. Such a length scale of `essential resolution of observation' for reconstruction 3D is close to the dissipation scale in three-dimensional NS turbulence. % Here we study the equivalent length scale in two-dimensional NS turbulence, 2D, and compare with the three-dimensional case. Our numerical studies using data assimilation and conditional Lyapunov exponents reveal that, for Kolmogorov flows with Ekman drag, the length scale 2D is actually close to the forcing scale, substantially larger than the dissipation scale. Furthermore, we discuss the origin of the significant relative difference between the length scales, 2D and 3D, based on inter-scale interactions, `cascades' and orbital instabilities in turbulence dynamics.