Abstract
Abstract Motivated by the potential of oceanic mesoscale eddies to drive intrinsic low-frequency variability, this paper examines geostrophic turbulence in the frequency–wavenumber domain. Frequency–wavenumber spectra, spectral fluxes, and spectral transfers are computed from an idealized two-layer quasigeostrophic (QG) turbulence model, a realistic high-resolution global ocean general circulation model, and gridded satellite altimeter products. In the idealized QG model, energy in low wavenumbers, arising from nonlinear interactions via the well-known inverse cascade, is associated with energy in low frequencies and vice versa, although not in a simple way. The range of frequencies that are highly energized and engaged in nonlinear transfer is much greater than the range of highly energized and engaged wavenumbers. Low-frequency, low-wavenumber energy is maintained primarily by nonlinearities in the QG model, with forcing and friction playing important but secondary roles. In the high-resolution ocean model, nonlinearities also generally drive kinetic energy to low frequencies as well as to low wavenumbers. Implications for the maintenance of low-frequency oceanic variability are discussed. The cascade of surface kinetic energy to low frequencies that predominates in idealized and realistic models is seen in some regions of the gridded altimeter product, but not in others. Exercises conducted with the general circulation model suggest that the spatial and temporal filtering inherent in the construction of gridded satellite altimeter maps may contribute to the discrepancies between the direction of the frequency cascade in models versus gridded altimeter maps seen in some regions. Of course, another potential reason for the discrepancy is missing physics in the models utilized here.
Highlights
Geostrophic turbulence and its progenitor twodimensional turbulence serve as valuable paradigms for atmospheric and oceanic flows
This paper addresses the relative contributions of forcing versus intrinsic nonlinearities in the maintenance of low-frequency variability in oceanic geostrophic turbulence
Penduff et al (2011) demonstrate that interannual variance of sea surface height in ocean general circulation models driven by atmospheric forcing fields that lack interannual variability is comparable to the variance in ocean models driven by interannually varying forcing fields
Summary
Geostrophic turbulence and its progenitor twodimensional turbulence serve as valuable paradigms for atmospheric and oceanic flows. Arbic et al (2012b, hereinafter ASFMRS) demonstrate that nonlinearities in an idealized, two-layer, f-plane, QG turbulence model forced by an imposed, baroclinically unstable, mean flow (e.g., Salmon 1978, 1980; Haidvogel and Held 1980; Larichev and Held 1995) drive energy toward longer time scales (lower frequencies), alongside the well-known inverse cascade to lower wavenumbers. The frequency domain spectral transfers and fluxes used in ASFMRS provide a new tool to measure the relative importance of nonlinear intrinsic processes versus forcing in the maintenance of lowfrequency oceanic variability. We utilize a highly idealized two-layer QG turbulence model on an f-plane with a flat bottom, forced by an imposed, horizontally homogeneous, vertically sheared mean flow that roughly represents oceanic gyres.
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.