Anisotropic characteristics of the Kraichnan direct cascade in two-dimensional hydrodynamic turbulence

Abstract

Statistical characteristics of the Kraichnan direct cascade for two-dimensional hydrodynamic turbulence are numerically studied (with spatial resolution 8192× 8192) in the presence of pumping and viscous-like damping. It is shown that quasi-shocks of vorticity and their Fourier partnerships in the form of jets introduce an essential influence in turbulence leading to strong angular dependencies for correlation functions. The energy distribution as a function of modulus k for each angle in the inertial interval has the Kraichnan behavior, k-4, and simultaneously a strong dependence on angles. However, angle average provides with a high accuracy the Kraichnan turbulence spectrum Ek=CKη2/3 k-3 where η is enstrophy flux and the Kraichnan constant CK 1.3, in correspondence with the previous simulations. Familiar situation takes place for third-order velocity structure function S3L which, as for the isotropic turbulence, gives the same scaling with respect to separation length R and η, S3L=C3η R3, but the mean over angles and time C3 differs from its isotropic value.