Effect of rotation on wake vortices in stratified flow

Abstract

Stratified wakes past an isolated conical seamount are simulated at a Froude number of Fr = 0.15 and Rossby numbers of Ro = 0.15, 0.75, and ∞. The wakes exhibit a K\' arm\' an vortex street, unlike their unstratified, non-rotating counterpart. Vortex structures are studied in terms of large-scale global modes, as well as spatially localised vortex evolution, with a focus on rotation effects. The global modes are extracted by spectral proper orthogonal decomposition (SPOD). For all three studied Ro ranging from mesoscale, submesoscale, and non-rotating cases, the frequency of the SPOD modes at different heights remains coupled as a global constant. However, the shape of the SPOD modes changes from slanted `tongues' at zero rotation (Ro=∞) to tall hill-height columns at strong rotation (Ro=0.15). A novel method for vortex centre tracking shows that, in all three cases, the vortices at different heights advect uniformly at about 0.9U∞ beyond the near wake, consistent with the lack of variability of the global modes. Under system rotation, cyclonic vortices (CVs) and anticyclonic vortices (AVs) present considerable asymmetry, especially at Ro = 0.75. The vorticity distribution as well as the stability of AVs are tracked downstream using statistics conditioned to the identified vortex centres. At Ro=0.75, intense AVs with relative vorticity up to ωz/f c=-2.4 are seen with small regions of instability but all AVs evolve towards a more stable state. Recent stability analysis that accounts for stratification and viscosity is found to improve on earlier criteria.