1. Seasonality of eddy kinetic energy in an eddy permitting global climate model
- Author
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Ryan Abernathey, Takaya Uchida, and Shafer Smith
- Subjects
Atmospheric Science ,010504 meteorology & atmospheric sciences ,010505 oceanography ,Mixed layer ,Turbulence ,Baroclinity ,Mesoscale meteorology ,Dissipation ,Geotechnical Engineering and Engineering Geology ,Oceanography ,Atmospheric sciences ,01 natural sciences ,Instability ,Climatology ,Middle latitudes ,Computer Science (miscellaneous) ,Environmental science ,Climate model ,Physics::Atmospheric and Oceanic Physics ,0105 earth and related environmental sciences - Abstract
We examine the seasonal cycle of upper-ocean mesoscale turbulence in a high resolution CESM climate simulation. The ocean model component (POP) has 0.1° resolution, mesoscale resolving at low and middle latitudes. Seasonally and regionally resolved wavenumber power spectra are calculated for sea-surface eddy kinetic energy (EKE). Although the interpretation of the spectral slopes in terms of turbulence theory is complicated by the strong presence of dissipation and the narrow inertial range, the EKE spectra consistently show higher power at small scales during winter throughout the ocean. Potential hypotheses for this seasonality are investigated. Diagnostics of baroclinc energy conversion rates and evidence from linear quasigeostrophic stability analysis indicate that seasonally varying mixed-layer instability is responsible for the seasonality in EKE. The ability of this climate model, which is not considered submesoscale resolving, to produce mixed layer instability although damped by dissipation, demonstrates the ubiquity and robustness of this process for modulating upper ocean EKE.
- Published
- 2017
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