Internal tide radiation from Mendocino Escarpment

Strong semidiurnal internal tides are observed near Mendocino Escarpment in full-depth profile time series of velocity, temperature, and salinity. Velocity and density profiles are combined to estimate the internal tide energy flux. Divergence of this flux demonstrates that its source is the barotro...

Full description

Saved in:
Bibliographic Details
Published inJournal of physical oceanography Vol. 33; no. 7; pp. 1510 - 1527
Main Authors ALTHAUS, Alana M, KUNZE, Eric, SANFORD, Thomas B
Format Journal Article
LanguageEnglish
Published Boston, MA American Meteorological Society 01.07.2003
Subjects
Coastal oceanography, estuaries. Regional oceanography
Diurnal variations
Earth, ocean, space
Energy
Escarpments
Exact sciences and technology
External geophysics
Fluctuations
Internal waves
Physics of the oceans
Temperature
Tides
Turbulence
Velocity
United States > US
Mendocino California
Pycnocline
Water mass
Turbulence
Intensity
Surface layer
Time series
Semidiurnal tide
Parameterization
Mass transfer
Internal energy
Salinity
Amplification
Mixed layer
Energy loss
Internal wave
Depth profile
Nutrient
Northeast Pacific
Stratification
Oceanic tide
Energy transfer
Non linear wave
Online AccessGet full text

Cover

More Information
Summary:Strong semidiurnal internal tides are observed near Mendocino Escarpment in full-depth profile time series of velocity, temperature, and salinity. Velocity and density profiles are combined to estimate the internal tide energy flux. Divergence of this flux demonstrates that its source is the barotropic tide interacting with the escarpment. A baroclinic energy flux of 7 kW m^sup -1^ radiates from the escarpment, corresponding to 3% of the 220 kW m^sup -1^ fluxing poleward in the surface tide. Energy and energy flux are concentrated in packets that emanate from the flanks of the ridge surmounting the escarpment and one site 90 km north of the escarpment. Coherent beamlike structure along semidiurnal ray paths remains identifiable until the first surface reflection. Beyond the first surface reflection north of the escarpment, the energy flux drops by 2 kW m^sup -1^ and beams are no longer discernible. Turbulence, as inferred from finescale paramelerizations, is elevated by over two orders of magnitude relative to the open-ocean interior in localized 500-m-thick layers at the bottom over the ridge crest, near the surface at the station closest to the first surface reflection to the north, slightly north of the first bottom reflection to the north, and on the south flank of the escarpment. Despite its intensity, turbulent dissipation integrated over the ridge crest is only 1% of the energy flux in the internal tides. Thus, the bulk of surface tidal losses at the escarpment is radiating away as internal waves. High turbulent dissipation rates near the surface reflection suggest that loss of energy flux there may be turbulent. This turbulence may arise from (i) Wentzel-Kramers-Brillouin amplification of semidiurnal shear as the internal tide propagates into high near-surface stratification or (ii) superposition of incident and reflected waves enhancing nonlinear transfers to small scales and turbulence production. Localized mixing due to internal tide beams impinging on the base of the mixed layer may be an important unconsidered cause of nutrient and water-mass fluxes between the surface layer and the upper pycnocline. [PUBLICATION ABSTRACT]
ISSN:0022-3670
1520-0485
DOI:10.1175/1520-0485(2003)033<1510:ITRFME>2.0.CO;2