Abstract
AbstractFine‐scale motions (<100 km) contribute significantly to the exchanges and dissipation of kinetic energy in the upper ocean. However, knowledge of ocean kinetic energy at fine‐scales (in terms of density and transfers) is currently limited due to the lack of sufficient observational data sets at these scales. The sea‐surface height measurements of the upcoming Surface Water and Ocean Topography (SWOT) altimeter mission should provide information on kinetic energy exchanges in the upper ocean down to 10–15 km. Numerical ocean models, able to describe ocean dynamics down to ∼10 km, have been developed in anticipation of the SWOT mission. In this study, we use two state‐of‐the‐art, realistic, North Atlantic simulations, with horizontal resolutions ∼1.5 km, to investigate the distribution and exchanges of kinetic energy at fine‐scales in the open ocean. Our results show that the distribution of kinetic energy at fine‐scales approximately follows the predictions of quasigeostrophic dynamics in summertime but is somewhat consistent with submesoscale fronts‐dominated regimes in wintertime. The kinetic energy spectral fluxes are found to exhibit both inverse and forward cascade over the top 1,000 m, with a maximum inverse cascade close to the average energy‐containing scale. The forward cascade is confined to the ocean surface and shows a strong seasonality, both in magnitude and range of scales affected. Our analysis further indicates that high‐frequency motions (<1 day) play a key role in the forward cascade and that the estimates of the spectral fluxes based on geostrophic velocities fail to capture some quantitative aspects of kinetic energy exchanges across scales.
Highlights
The ocean is a turbulent fluid with a broad range of energetic scales, ranging from large ∼ O(1000 km) to centimeter scales
In order to show how sensitive the estimated slopes are to the selected wavelength range, we present in Figure 7a the average kinetic energy (KE) wavenumber spectral density and slope for box 3 in March for three different selected wavenumber ranges
We presented the analysis of kinetic energy wavenumber spectral density, slope, and flux by using datasets from daily and hourly outputs of two submesoscale permitting ocean models of the North Atlantic
Summary
We used two submesoscale permitting ocean models of the North Atlantic Ocean to investigate kinetic energy exchanges at fine-scales. KE fluxes at fine-scales are strongly impacted by submesoscale turbulence with a stronger forward cascade in winter within the mixed-layer. Not accounting for ageostrophic motions yields a significant under-estimation of the forward cascade
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