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1. Fate of Internal Waves on a Shallow Shelf

   https://doi.org/10.1029/2019JC015377  

   Davis, Kristen A.; Arthur, Robert S.; Reid, Emma C.; Rogers, Justin S.; Fringer, Oliver B.; DeCarlo, Thomas M.; Cohen, Anne L. (May 2020, Journal of Geophysical Research: Oceans)

   Abstract Internal waves strongly influence the physical and chemical environment of coastal ecosystems worldwide. We report novel observations from a distributed temperature sensing (DTS) system that tracked the transformation of internal waves from the shelf break to the surf zone over a narrow shelf slope region in the South China Sea. The spatially continuous view of temperature fields provides a perspective of physical processes commonly available only in laboratory settings or numerical models, including internal wave reflection off a natural slope, shoreward transport of dense fluid within trapped cores, and observations of internal rundown (near‐bed, offshore‐directed jets of water preceding a breaking internal wave). Analysis shows that the fate of internal waves on this shelf—whether transmitted into shallow waters or reflected back offshore—is mediated by local water column density structure and background currents set by the previous shoaling internal waves, highlighting the importance of wave‐wave interactions in nearshore internal wave dynamics. 

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2. (2014) Oregon Slope Base Seafloor (RS01SLBS)

   https://doi.org/10.58046/ooi-rs01slbs  

   NSF_Ocean_Observatories_Initiative (January 2014, US NSF Ocean Observatories Initiative)

   The Oregon Slope Base Seafloor site is located adjacent to the continental slope off the coast of Oregon at a water depth of ~2,900 meters. The site contains a Medium-Power junction box (MJ01A) and a Low-Power junction box (LJ01A). Here, ocean water properties are profoundly impacted by the California Current and internal waves. The coastal region of the Pacific Northwest is a classic wind-driven upwelling system where nutrient-rich deep waters rise to replace warmer surface waters, resulting in high marine productivity that attracts zooplankton, fish, and marine mammals. Near-bottom fauna are periodically negatively impacted by the flow of deep waters with very low oxygen concentrations (hypoxic events), and upwelling of corrosive, acidified waters onto the continental shelf. This area is also adjacent to the Cascadia Subduction Zone, which is characterized by episodic seismic tremors. The seafloor junction boxes contain geophysical and near seafloor water column instrumentation, and are attached to an electro-optical cable that provides significant power and 1 Gb two-way communications bandwidth. This seafloor site is also co-located with a Deep and Shallow Profiler Mooring, which collect complementary water column data. When coupled with other Cabled Array and Endurance Array installations off the central Oregon coast, the Slope Base infrastructure allows for measurements of a variety of coastal phenomena, including cross-shelf and along-shelf variability. 

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3. (2014) Oregon Slope Base Shallow Profiler Mooring (RS01SBPS)

   https://doi.org/10.58046/ooi-rs01sbps  

   NSF_Ocean_Observatories_Initiative (January 2014, US NSF Ocean Observatories Initiative)

   The Oregon Slope Base Shallow Profiler Mooring is situated adjacent to the continental slope off the coast of Oregon at ~2,900 meters water depth. Here, ocean water properties are profoundly impacted by the California Current and internal waves. The coastal region of the Pacific Northwest is a classic wind-driven upwelling system where nutrient-rich deep waters rise to replace warmer surface waters, resulting in high marine productivity that attracts zooplankton, fish, and marine mammals. Near-bottom fauna are periodically negatively impacted by the flow of deep waters with very low oxygen concentrations (hypoxic events), and upwelling of corrosive, acidified waters onto the continental shelf. This two-legged mooring is attached to an electro-optical cable that supplies power and bandwidth and hosts a Shallow Profiler (SF01B), a 200m Platform (PC01B), and a Winch Controller (SC01B). The 200 m platform and Shallow Profiler both house scientific instrumentation, and the profiler is tethered to a mooring-mounted winch that allows it to travel across a fixed depth in the water column (20 m to 200 m below sea surface), determined by currents and wave conditions at the surface. The mooring is co-located with a Low-Power junction box that collects complementary data near the seafloor. When coupled with other Cabled Array and Endurance Array installations off the central Oregon coast, the Slope Base Shallow Profiler Mooring allows for measurements of a variety of coastal phenomena, including cross-shelf and along-shelf variability. 

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4. Direct measurements reveal instabilities and turbulence within large amplitude internal solitary waves beneath the ocean

   https://doi.org/10.1038/s43247-020-00083-6  

   Chang, Ming-Huei; Cheng, Yu-Hsin; Yang, Yiing Jang; Jan, Sen; Ramp, Steven R.; Reeder, D. Benjamin; Hsieh, Wan-Ting; Ko, Dong S.; Davis, Kristen A.; Shao, Huan-Jie; et al (December 2021, Communications Earth & Environment)

   null (Ed.)

   Abstract Internal solitary waves are ubiquitous in coastal regions and marginal seas of the world’s oceans. As the waves shoal shoreward, they lose the energy obtained from ocean tides through globally significant turbulent mixing and dissipation and consequently pump nutrient-rich water to nourish coastal ecosystem. Here we present fine-scale, direct measurements of shoaling internal solitary waves in the South China Sea, which allow for an examination of the physical processes triggering the intensive turbulent mixing in their interior. These are convective breaking in the wave core and the collapse of Kelvin–Helmholtz billows in the wave rear and lower periphery of the core, often occurring simultaneously. The former takes place when the particle velocity exceeds the wave’s propagating velocity. The latter is caused by the instability induced by the strong velocity shear overcoming the stratification. The instabilities generate turbulence levels four orders of magnitude larger than that in the open ocean. 

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5. Lifecycle of a Submesoscale Front Birthed from a Nearshore Internal Bore

   https://doi.org/10.1175/JPO-D-21-0062.1  

   Haney, Sean R.; Simpson, Alexandra J.; McSweeney, Jacqueline M.; Waterhouse, Amy F.; Haller, Merrick C.; Lerczak, James A.; Barth, John A.; Lenain, Luc; Palóczy, André; Adams, Kate; et al (September 2021, Journal of Physical Oceanography)

   Abstract The ocean is home to many different submesoscale phenomena, including internal waves, fronts, and gravity currents. Each of these processes entail complex nonlinear dynamics, even in isolation. Here we present shipboard, moored, and remote observations of a submesoscale gravity current front created by a shoaling internal tidal bore in the coastal ocean. The internal bore is observed to flatten as it shoals, leaving behind a gravity current front that propagates significantly slower than the bore. We posit that the generation and separation of the front from the bore is related to particular stratification ahead of the bore, which allows the bore to reach the maximum possible internal wave speed. After the front is calved from the bore, it is observed to propagate as a gravity current for ≈4 hours, with associated elevated turbulent dissipation rates. A strong cross-shore gradient of along-shore velocity creates enhanced vertical vorticity (Rossby number ≈ 40) that remains locked with the front. Lateral shear instabilities develop along the front and may hasten its demise. 

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