Seasonality of submesoscale flows in the ocean surface boundary layer
Geophysical Research Letters AGU Publications 43:5 (2016) 2118-2126
Abstract:
A signature of submesoscale flows in the upper ocean is skewness in the distribution of relative vorticity. Expected to result for high Rossby number flows, such skewness has implications for mixing, dissipation, and stratification within the upper ocean. An array of moorings deployed in the Northeast Atlantic for 1 year as part of the experiment of the Ocean Surface Mixing, Ocean Submesoscale Interaction Study (OSMOSIS) reveals that relative vorticity is positively skewed during winter even though the scale of the Rossby number is less than 0.5. Furthermore, this skewness is reduced to zero during spring and autumn. There is also evidence of modest seasonal variations in the gradient Rossby number. The proposed mechanism by which relative vorticity is skewed is that the ratio of lateral to vertical buoyancy gradients, as summarized by the inverse gradient Richardson number, restricts its range during winter but less so at other times of the year. These results support recent observations and model simulations suggesting that the upper ocean is host to a seasonal cycle in submesoscale turbulence.Gill’s model of the Antarctic Circumpolar Current, revisited: The role of latitudinal variations in wind stress
Ocean Modelling Elsevier 97 (2015) 37-51
Abstract:
Gill’s (1968) model of the Antarctic Circumpolar Current (ACC) is reinterpreted for a stratified, reduced-gravity ocean, where the barotropic streamfunction is replaced by the pycnocline depth, and the bottom drag coefficient by the Gent and McWilliams eddy diffusivity. The resultant model gives a simple description of the lateral structure of the ACC that is consistent with contemporary descriptions of ACC dynamics. The model is used to investigate and interpret the sensitivity of the ACC to the latitudinal profile of the surface wind stress. A substantial ACC remains when the wind jet is shifted north of the model Drake Passage, even by several thousand kilometers. The integral of the wind stress over the circumpolar streamlines is found to be a useful predictor of the magnitude of the volume transport through the model Drake Passage, although it is necessary to correct for basin-wide zonal pressure gradients in order to obtain good quantitative agreement.On the dynamical influence of ocean eddy potential vorticity fluxes
Ocean Modelling Elsevier 92 (2015) 169-182
The seasonal cycle of submesoscale flows
Ocean Modelling Elsevier 92 (2015) 69-84
The role of ocean gateways in the dynamics and sensitivity to wind stress of the early Antarctic Circumpolar Current
Paleoceanography and Paleoclimatology American Geophysical Union (AGU) 30:3 (2015) 284-302