Vortical and Wave Modes in 3D Rotating Stratified Flows: Random Large Scale Forcing

Abstract

Utilizing an eigenfunction decomposition, we study the growth and spectra of energy in the vortical and wave modes of a 3D rotating stratified fluid as a function of ε = f/N. Working in regimes characterized by moderate Burger numbers, i.e. Bu = 1/ε2 < 1 or Bu 1, our results indicate profound change in the character of vortical and wave mode interactions with respect to Bu = 1. As with the reference state of ε=1, for ε < 1 the wave mode energy saturates quite quickly and the ensuing forward cascade continues to act as an efficient means of dissipating ageostrophic energy. Further, these saturated spectra steepen as ε decreases: we see a shift from k-1 to k-5/3 scaling for kf < k < kd (where kf and kd are the forcing and dissipation scales, respectively). On the other hand, when ε > 1 the wave mode energy never saturates and comes to dominate the total energy in the system. In fact, in a sense the wave modes behave in an asymmetric manner about ε = 1. With regard to the vortical modes, for ε 1, the signatures of 3D quasigeostrophy are clearly evident. Specifically, we see a k-3 scaling for kf < k < kd and, in accord with an inverse transfer of energy, the vortical mode energy never saturates but rather increases for all k < kf. In contrast, for ε > 1 and increasing, the vortical modes contain a progressively smaller fraction of the total energy indicating that the 3D quasigeostrophic subsystem plays an energetically smaller role in the overall dynamics.