Climate Process Team on Internal Wave–Driven Ocean Mixing

MacKinnon, Jennifer A.; Zhao, Zhongxiang; Whalen, Caitlin B.; Waterhouse, Amy F.; Trossman, David S.; Sun, Oliver; Laurent, Louis C. St.; Simmons, Harper L.; Polzin, Kurt L.; Pinkel, Robert; Pickering, Andrew I.; Norton, Nancy J.; Nash, Jonathan D.; Musgrave, Ruth; Merchant, Lynne M.; Melet, Angélique; Mater, Benjamin D.; Legg, Sonya; Large, William G.; Kunze, Eric; Klymak, Jody M.; Jochum, Markus; Jayne, Steven R.; Hallberg, Robert; Griffies, Stephen M.; Diggs, Stephen; Danabasoglu, Gökhan; Chassignet, Eric P.; Buijsman, Maarten C.; Bryan, Frank O.; Briegleb, Bruce P.; Barna, Andrew; Arbic, Brian K.; Ansong, Joseph K.; Alford, Matthew H.

doi:10.1175/bams-d-16-0030.1

Cited by 261 publications

(215 citation statements)

References 208 publications

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“…Therefore, we should resolve the internal tide's multimodal structure in order to quantify the fate of internal tides. The information may be useful to examine the near‐field and far‐field tidal dissipation (Jayne & Laurent, , Klymak et al, , St. Laurent et al, ), with a long‐term goal of parameterization of the tide‐driven ocean mixing in the global ocean (MacKinnon et al, ).…”

Section: Discussionmentioning

confidence: 99%

The Global Mode‐2 M₂ Internal Tide

Zhao

2018

JGR Oceans

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The mode‐2 M2 internal tide is observed from satellite altimetry. It is extracted in two steps: First, the mode‐2 component is separated from modes 1 and 3 by a bandpass filter with cutoff wavelengths of [0.85 1.35]×λ2, where λ2 is the mode‐2 wavelength; and second, three mode‐2 internal tidal waves are extracted by fitting plane waves in each 120 km by 120 km window. The satellite‐observed mode‐2 M2 internal tide underestimates its strength: It contains the phase‐locked component only, missing the time‐varying component; it contains the southbound/northbound component only, missing the eastbound/westbound component. The satellite results provide rich information on the global mode‐2 M2 internal tide. The results show that the mode‐2 M2 internal tide is ubiquitous in the ocean, and its sea surface height amplitudes are O (1 mm). The spatial patterns of mode‐1 and mode‐2 internal tides are very different. Mode 1 mainly originates at steep topographic features such as submarine ridges, but mode 2 is also generated at gentler topographic features such as abyssal seamounts and fracture zones. Mode‐1 beams propagate O (1,000 km), while mode‐2 beams can be tracked for O (100 km). Depth‐integrated energy and flux are calculated using sea surface height amplitudes and conversion functions built from the World Ocean Atlas 2013. The globally integrated energy of the mode‐2 M2 internal tide approximates to 8 PJ, about 22% of mode 1 (36.4 PJ). This work suggests that higher‐mode internal tides play an important role in the tidal energetics, in particular, over abyssal seamounts and fracture zones.

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Section: Discussionmentioning

confidence: 99%

The Global Mode‐2 M₂ Internal Tide

Zhao

2018

JGR Oceans

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“…The vertical variations in internal tide propagation and dissipation have been too complex to understand until now due to the high expense of such measurements and limited field observations (Kerry et al, ). A well‐depicted horizontal propagation path is an important step toward correctly parameterizing the spatial distribution of diapycnal mixing in the global domain (MacKinnon et al, ). Furthermore, multiwave interference processes are widespread in the open ocean because of the long‐range propagation and numerous source distributions (Zhao et al, ).…”

Section: Introductionmentioning

confidence: 99%

Long‐Range Radiation and Interference Pattern of Multisource M₂ Internal Tides in the Philippine Sea

Wang

Yin

et al. 2018

JGR Oceans

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Long‐range radiation and interference of M2 internal tides from multiple sources in the Philippine Sea are examined by driving a high‐resolution numerical model. The M2 internal tides are effectively generated around the boundary area, which includes the Luzon Strait, Ryukyu Island chain, Bonin Ridge, Mariana Arc, and Izu Ridge, favoring the occurrence of complex interference patterns. The local sources (mainly Daito Islands and Palau Ridge) inside the basin contribute to a small portion (~5%) of total energy but enhance the geographical inhomogeneity of the baroclinic field. The mode‐1 and mode‐2 M2 tidal beams from boundary sources radiate a long distance into the basin but exhibit different interference‐modulated geography variations. A 2‐D line source model characterizing interference can reproduce the general baroclinic field. Two notable interference cases are investigated: (1) the superposition of internal tides from Luzon Strait and Miyako Strait bifurcates into several southeastward beams, consistent with previous numerical simulations and altimeter measurements, and (2) the interference between Tokara Strait and Bonin Ridge exhibits a multiscale spatial pattern, which is modulated by the local generated energy and bathymetry features. Energetic dissipation occurs both near the boundary sources and in the basin. A locally dissipated fraction q of ~0.4 is estimated at the Luzon Strait and Bonin Ridge with continuous bathymetry features, while q of ~0.6 is estimated at the Ryukyu Island chain and Mariana Arc with discrete topographic variability. A lower locally dissipated fraction indicates a stronger energy flux radiating into the basin, where enhanced dissipation coincides closely with the interference‐modulated flux field.

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“…These waves propagate both vertically and horizontally, carrying wave energy away from their generation site [2]. When the waves break, that energy can be used for turbulent mixing of heat and salt.…”

Section: Introductionmentioning

confidence: 99%

“…While internal tides are generated on horizontal scales of order 1-100 km, and break through overturning on much smaller scales, global climate models typically have resolutions of order 10-100 km, allowing resolution of the generation and propagation of only the large-scale internal tides and none of the wave-breaking and mixing processes [2]. The diapycnal mixing that results from internal tide breaking must therefore be parameterized.…”

Section: Introductionmentioning

confidence: 99%

The Impact of Topographic Steepness on Tidal Dissipation at Bumpy Topography

Legg

Nazarian

2017

Fluids

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Breaking internal waves are an important contributor to mixing in the stratified ocean interior. We use two-dimensional, nonhydrostatic numerical simulations to examine the breaking of internal waves generated by tidal flow over sinusoidal bottom topography. We explore the sensitivity of the internal wave breaking to the topographic steepness and Coriolis frequency, focusing on the vertical structure of kinetic energy dissipation and the ratio of local dissipation to the barotropic-to-baroclinic energy conversion. When the tidal frequency is twice the local Coriolis frequency, wave breaking above the topography is driven by wave-wave interactions which transfer wave energy from the tidal forcing frequency to the inertial frequency. The greater shear associated with the inertial frequency waves leads to enhanced dissipation in a thick layer above the topography. The topographic steepness strongly modulates this dependence of dissipation on Coriolis frequency; for some steep sinusoidal topographies, most wave energy propagates downward into the topographic troughs, eliminating the possibility for significant breaking above the topographic peaks. Current parameterizations of tidal dissipation in use in global ocean models need to be adapted to include the dependence of the local dissipation on both the Coriolis frequency and the topographic steepness.

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Climate Process Team on Internal Wave–Driven Ocean Mixing

Cited by 261 publications

References 208 publications

The Global Mode‐2 M₂ Internal Tide

The Global Mode‐2 M₂ Internal Tide

Long‐Range Radiation and Interference Pattern of Multisource M₂ Internal Tides in the Philippine Sea

The Impact of Topographic Steepness on Tidal Dissipation at Bumpy Topography

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Climate Process Team on Internal Wave–Driven Ocean Mixing

Cited by 261 publications

References 208 publications

The Global Mode‐2 M2 Internal Tide

The Global Mode‐2 M2 Internal Tide

Long‐Range Radiation and Interference Pattern of Multisource M2 Internal Tides in the Philippine Sea

The Impact of Topographic Steepness on Tidal Dissipation at Bumpy Topography

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Product

Resources

About

The Global Mode‐2 M₂ Internal Tide

The Global Mode‐2 M₂ Internal Tide

Long‐Range Radiation and Interference Pattern of Multisource M₂ Internal Tides in the Philippine Sea