Analyses of fluctuations of low frequency signals (300 ± 30 Hz) propagating in shallow water in the presence of nonlinear internal waves (NIWs) in the Shallow Water 2006 experiment are carried out. Signals were received by a vertical line array at a distance of ∼20 km from the source. A NIW train was moving totally inside of the acoustic track, and the angle between the wave front of the NIW and the acoustic track in the horizontal plane was ∼10°. It is shown that the spectrum of the sound intensity fluctuations contains peaks corresponding to the coupling of pairs of propagating modes. Analysis of spectra at different hydrophone depths, and also summed over depth allows the authors to estimate attenuation in the bottom sediments.

Kunze E. Internal-Wave-Driven Mixing: Global Geography and Budgets. 来源: Journal of Physical Oceanography, 2017, 47(6). 摘要: Internal-wave-driven dissipation rates ε and diapycnal diffusivities K are inferred globally using a finescale parameterization based on vertical strain applied to ~30,000 hydrographic casts. Global dissipations are 2.0 ± 0.6 TW, consistent with internal-wave power sources of 2.1 ± 0.7 TW from tides and wind. Vertically-integrated dissipation rates vary by 3-4 orders of magnitude with elevated values over abrupt topography in the western Indian and Pacific, as well as mid-ocean slow spreading ridges, consistent with internal tide sources. But dependence on bottom forcing is much weaker than linear wave generation theory, pointing to horizontal dispersion by internal waves and relatively little local dissipation. Stratified turbulent bottom-boundary-layer thickness variability is not consistent with OGCM parameterizations of tidal mixing. Average diffusivities K = (0.3-0.4) × 10–4 m² s–1 depend only weakly on depth, indicating that ε = KN²/γ scales as N² such that the bulk of the dissipation is in the pycnocline and less than 0.08 TW dissipation below 2000-m depth. Average diffusivities K approach 10–4 m² s–1 in the bottom 500 mab in height-above-bottom coordinates with a 2000-m e-folding scale. Average dissipation rates ε are 10–9 W kg–1 within 500 mab then diminish to background deep values of 0.15 × 10–9 W kg–1 by 1000 mab. No conclusive support is found for high dissipation rates in Antarctic Circumpolar Currents, or parametric subharmonic instability being a significant pathway to elevated dissipation rates for semidiurnal or diurnal internal tides equatorward of 28° and 14° latitudes, respectively. Internal-wave-driven dissipation rates ε and diapycnal diffusivities K are inferred globally using a finescale parameterization based on vertical strain applied to ~30,000 hydrographic casts. Global dissipations are 2.0 ± 0.6 TW, consistent with internal-wave power sources of 2.1 ± 0.7 TW from tides and wind. Vertically-integrated dissipation rates vary by 3-4 orders of magnitude with elevated values over abrupt topography in the western Indian and Pacific, as well as mid-ocean slow spreading ridges, consistent with internal tide sources. But dependence on bottom forcing is much weaker than linear wave generation theory, pointing to horizontal dispersion by internal waves and relatively little local dissipation. Stratified turbulent bottom-boundary-layer thickness variability is not consistent with OGCM parameterizations of tidal mixing. Average diffusivities K = (0.3-0.4) × 10–4 m² s–1 depend only weakly on depth, indicating that ε = KN²/γ scales as N² such that the bulk of the dissipation is in the pycnocline and less than 0.08 TW dissipation below 2000-m depth. Average diffusivities K approach 10–4 m² s–1 in the bottom 500 mab in height-above-bottom coordinates with a 2000-m e-folding scale. Average dissipation rates ε are 10–9 W kg–1 within 500 mab then diminish to background deep values of 0.15 × 10–9 W kg–1 by 1000 mab. No conclusive support is found for high dissipation rates in Antarctic Circumpolar Currents, or parametric subharmonic instability being a significant pathway to elevated dissipation rates for semidiurnal or diurnal internal tides equatorward of 28° and 14° latitudes, respectively 全文链接：https://journals.ametsoc.org/doi/10.1175/JPO-D-16-0141.1