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Stalling and Dissipation of a Near‐Inertial Wave (NIW) in an Anticyclonic Ocean Eddy: Direct Determination of Group Velocity and Comparison With Theory
Author(s) -
Sanford Thomas B.,
Ma Barry B.,
Alford Matthew H.
Publication year - 2021
Publication title -
journal of geophysical research: oceans
Language(s) - English
Resource type - Journals
eISSN - 2169-9291
pISSN - 2169-9275
DOI - 10.1029/2020jc016742
Subject(s) - inertial wave , dissipation , mechanics , eddy diffusion , energy flux , mesoscale meteorology , vorticity , turbulence , group velocity , geology , physics , wavenumber , geophysics , meteorology , wave propagation , vortex , optics , mechanical wave , thermodynamics , longitudinal wave , astronomy
A near‐inertial wave stalling and breaking in a critical layer was observed for a week by a pair of autonomous velocity and density profilers on concentric paths in an ocean mesoscale eddy. Profiler observations provide estimates of the eddy's vertical vorticity and shear, quantities needed to test theories of downward near‐inertial wave (NIW) energy flux and loss from inertial wave–eddy interactions. The unique observations of the wave's intrinsic frequencyω iand vertical wavenumber m provide a novel estimate of the vertical group velocity C gz from changes inω iwith respect to m . Shear, strain, energy flux convergence, and parameterized turbulence are all elevated near 140 m depth, near the bottom of the strongest eddy velocities. Our observations are consistent with a downgoing NIW's group velocity decreasing owing to wave–eddy interactions, providing important clues on global energetics of NIW mixing.