Direct observational evidence of an oceanic dual kinetic energy cascade and its seasonality

Balwada, Dhruv; Xie, Jin; Marino, Raffaele; Feraco, Fabio

doi:10.1126/sciadv.abq2566

Cited by 36 publications

(25 citation statements)

References 62 publications

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“…(2022) where they use a spatial filter to examine the KE spectra and cross‐scale transfer, Lindborg (2015), Balwada et al. (2016, 2022), LaCasce (2016), Poje et al. (2017), and Pearson et al.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

Wavelet‐Based Wavenumber Spectral Estimate of Eddy Kinetic Energy: Idealized Quasi‐Geostrophic Flow

Uchida

Jamet

Poje

et al. 2023

J Adv Model Earth Syst

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A wavelet‐based method is re‐introduced in an oceanographic and spectral context to estimate wavenumber spectrum and spectral flux of kinetic energy and enstrophy. We apply this to a numerical simulation of idealized, doubly periodic quasi‐geostrophic flows, that is, the flow is constrained by the Coriolis force and vertical stratification. The double periodicity allows for a straightforward Fourier analysis as the baseline method. Our wavelet spectra agree well with the canonical Fourier approach but with the additional strengths of negating the necessity for the data to be periodic and being able to extract local anisotropies in the flow. Caution is warranted, however, when computing higher‐order quantities, such as spectral flux.

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Section: Conclusion and Discussionmentioning

confidence: 99%

Wavelet‐Based Wavenumber Spectral Estimate of Eddy Kinetic Energy: Idealized Quasi‐Geostrophic Flow

Uchida

Jamet

Poje

et al. 2023

J Adv Model Earth Syst

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show abstract

“…The observations analyzed here demonstrate a large forward energy transfer localized at fronts, although not exclusively during active large‐scale frontogenesis. Recent work in the Gulf of Mexico, another region with an active submesoscale, has hinted that a forward cascade of kinetic energy occurs at scales of 500 m–5 km (Balwada et al., 2022) in observations (with smaller scales during the summer) and at scales of 5 km in models (Srinivasan et al., 2023).…”

Section: Discussionmentioning

confidence: 99%

Characterizing the Role of Non‐Linear Interactions in the Transition to Submesoscale Dynamics at a Dense Filament

Freilich

Lenain

Gille

2023

Geophysical Research Letters

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Ocean dynamics at the submesoscale play a key role in mediating upper‐ocean energy dissipation and dispersion of tracers. Observations of ocean currents from synoptic mesoscale surveys at submesoscale resolution (250 m–100 km) from a novel airborne instrument (MASS DoppVis) reveal that the kinetic energy spectrum in the California Current System is nearly continuous from 100 km to sub‐kilometer scales, with a k−2 spectral slope. Although there is not a transition in the kinetic energy spectral slope, there is a transition in the dynamics to non‐linear ageostrophic interactions at scales of (1 km). Kinetic energy transfer across spatial scales is enabled by interactions between the rotational and divergent components of the flow field at the submesoscale. Kinetic energy flux is patchy and localized at submesoscale fronts. Kinetic energy is transferred both downscale and upscale from 1 km in the observations of a cold filament.

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“…It uses a diffusion-type coarse-graining method that is made available to users through Python utilities. Another approach applies structure functions to Lagrangian trajectories to extract spectral diagnostics, such as power spectra and inter-scale energy transfers (Frisch (1995), Balwada et al (2022)).…”

Section: State Of the Fieldmentioning

confidence: 99%

FlowSieve: A Coarse-Graining Utility for Geophysical Flows on the Sphere

Storer¹,

Aluie²

2023

JOSS

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Ocean and atmosphere dynamics span an incredibly wide range of spatial and temporal scales, with spatial scales ranging from the sub-millimetre viscous scales all the way up to planetary scales at tens of thousands of kilometres. Because of the strong non-linear nature of oceanic and atmospheric flows, not only do the behaviour and characteristics change significantly with scale, but important energetic interactions exist between different scales. As a result, an important step in understanding and predicting the behaviour of such complex flow systems is being able to disentangle the complex interactions across this wide range of scales. Coarse-graining is a physically-motivated and mathematically-rigorous technique for partitioning spatial flows as a function of a specified partitioning scale, allowing for a consistent and comprehensive scale-by-scale analysis.

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Direct observational evidence of an oceanic dual kinetic energy cascade and its seasonality

Cited by 36 publications

References 62 publications

Wavelet‐Based Wavenumber Spectral Estimate of Eddy Kinetic Energy: Idealized Quasi‐Geostrophic Flow

Wavelet‐Based Wavenumber Spectral Estimate of Eddy Kinetic Energy: Idealized Quasi‐Geostrophic Flow

Characterizing the Role of Non‐Linear Interactions in the Transition to Submesoscale Dynamics at a Dense Filament

FlowSieve: A Coarse-Graining Utility for Geophysical Flows on the Sphere

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