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Damping of Inertial Motions through the Radiation of Near-Inertial Waves in a Dipole Vortex in the Iceland Basin

Thomas, Leif N. ; Skyllingstad, Eric D. ; Rainville, Luc ; [et al.]

American Meteorological Society ; 2023

In: Journal of Physical Oceanography Vol. 53, No. 8 ( 2023-08), p. 1821-1833

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In: Journal of Physical Oceanography, American Meteorological Society, Vol. 53, No. 8 ( 2023-08), p. 1821-1833

Abstract: Along with boundary layer turbulence, downward radiation of near-inertial waves (NIWs) damps inertial oscillations (IOs) in the surface ocean; however, the latter can also energize abyssal mixing. Here we present observations made from a dipole vortex in the Iceland Basin where, after the period of direct wind forcing, IOs lost over half their kinetic energy (KE) in two inertial periods to radiation of NIWs with minimal turbulent dissipation of KE. The dipole’s vorticity gradient led to a rapid reduction in the NIW’s lateral wavelength via ζ refraction that was accompanied by isopycnal undulations below the surface mixed layer. Pressure anomalies associated with the undulations were correlated with the NIW’s velocity yielding an energy flux of 310 mW m −2 pointed antiparallel to the vorticity gradient and a downward flux of 1 mW m −2 capable of driving the observed drop in KE. The minimal role of turbulence in the energetics after the IOs had been generated by the winds was confirmed using a large-eddy simulation driven by the observed winds. Significance Statement We report direct observational estimates of the vector wave energy flux of a near-inertial wave. The energy flux points from high to low vorticity in the horizontal, consistent with the theory of ζ refraction. The downward energy flux dominates the observed damping of inertial motions over turbulent dissipation and mixing.

Type of Medium: Online Resource

ISSN: 0022-3670 , 1520-0485

URL: Article

DOI: 10.1175/JPO-D-22-0202.1

Language: Unknown

Publisher: American Meteorological Society

Publication Date: 2023

detail.hit.zdb_id: 2042184-9

detail.hit.zdb_id: 184162-2

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Boundary Layer Energetics of Rapid Wind and Wave Forced Mixing Events

Skyllingstad, Eric D. ; Samelson, Roger M. ; Simmons, Harper ; [et al.]

American Meteorological Society ; 2023

In: Journal of Physical Oceanography Vol. 53, No. 8 ( 2023-08), p. 1887-1900

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In: Journal of Physical Oceanography, American Meteorological Society, Vol. 53, No. 8 ( 2023-08), p. 1887-1900

Abstract: The observed development of deep mixed layers and the dependence of intense, deep-mixing events on wind and wave conditions are studied using an ocean LES model with and without an imposed Stokes-drift wave forcing. Model results are compared to glider measurements of the ocean vertical temperature, salinity, and turbulence kinetic energy (TKE) dissipation rate structure collected in the Icelandic Basin. Observed wind stress reached 0.8 N m −2 with significant wave height of 4–6 m, while boundary layer depths reached 180 m. We find that wave forcing, via the commonly used Stokes drift vortex force parameterization, is crucial for accurate prediction of boundary layer depth as characterized by measured and predicted TKE dissipation rate profiles. Analysis of the boundary layer kinetic energy (KE) budget using a modified total Lagrangian-mean energy equation, derived for the wave-averaged Boussinesq equations by requiring that the rotational inertial terms vanish identically as in the standard energy budget without Stokes forcing, suggests that wind work should be calculated using both the surface current and surface Stokes drift. A large percentage of total wind energy is transferred to model TKE via regular and Stokes drift shear production and dissipated. However, resonance by clockwise rotation of the winds can greatly enhance the generation of inertial current mean KE (MKE). Without resonance, TKE production is about 5 times greater than MKE generation, whereas with resonance this ratio decreases to roughly 2. The results have implications for the problem of estimating the global kinetic energy budget of the ocean.

Type of Medium: Online Resource

ISSN: 0022-3670 , 1520-0485

URL: Article

DOI: 10.1175/JPO-D-22-0150.1

Language: Unknown

Publisher: American Meteorological Society

Publication Date: 2023

detail.hit.zdb_id: 2042184-9

detail.hit.zdb_id: 184162-2

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