Scaling laws and local enhancements of buoyancy flux in stratified turbulent flows

Abstract

In the presence of stratification, turbulent flows exhibit intermittency not only at small scales but also at large scales, comparable to the mean flow, as observed in the atmosphere and oceans. We study such flows through a large parametric exploration using direct numerical simulations of the Boussinesq equations with different forcing types. We examine two Prandtl numbers (1 and 6) and vary the Froude number (Fr) over a range of geophysical interest values, 0.01 Fr 1, corresponding to a variation in terms of the buoyancy Reynolds number (RIB) of 0.06 RIB 2300. We analyze the dependence on RIB of the buoyancy flux (Bf), the mixing efficiency, the shear parameters, and the vertical momentum flux. Strongly non-Gaussian tails in the spatio-temporal distribution of the Bf are observed, with kurtosis reaching ≈ 102, indicating the potential for stratified geophysical flows to be characterized by highly variable transport properties along the direction of gravity even under stable stratification. This is associated with long-time intermittent behavior of vertical velocity and temperature at large scale, which produces local turbulence and enhances dissipation and transport. We present evidence that the skewness of Bf increases with RIB as a power-law and saturates in the passive-scalar limit. We also show that the domain-averaged Bf exhibits two distinct trends: logarithmic growth with RIB and approach to a small offset as stratification strengthens. A simple model for the temporal evolution of energy and Bf indicates that the defect between vertical and potential energy drives strong Bf events. This trend directly leads to convective instabilities, the formation of two-dimensional and three-dimensional eddies, and rapid dissipation on a turnover timescale, allowing the energetic cycle to restart-also occurring in bursts.