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1. (2014) Coastal Pioneer New England Shelf Mobile Assets (CP05MOAS)

   https://doi.org/10.58046/ooi-cp05moas  

   NSF_Ocean_Observatories_Initiative (January 2014, US NSF Ocean Observatories Initiative)

   Two kinds of Mobile Assets survey the area in and around the array of moorings at the Coastal Pioneer Array – Coastal Gliders and Coastal Autonomous Underwater Vehicles (AUVs).\n\nAn array of 6 Coastal Gliders (Teledyne-Webb Slocum Gliders) sample large, mesoscale features through a broad region (130 x 185 km) of the outer continental shelf between the shelf break and the Gulf Stream. The role of these gliders in monitoring this broader area is to resolve rings, eddies and meanders from the Gulf Stream as they impinge on the shelf break front. These Teledyne-Webb Slocum Gliders fly through the water column along saw-tooth paths, penetrating the sea surface and diving down to a maximum depth of 1000 meters.\n\nAn array of two Coastal AUVs (REMUS-600 AUVs) travel along transects across the shelf-break frontal system extending beyond the mooring array, covering an area approximately 80 x 100 km in size centered on the array of moorings. The primary role of the AUVs is to resolve cross- and along-front “eddy fluxes” due to frontal instabilities, wind forcing, and mesoscale variability. These AUVs travel along saw-toothed transects, penetrating the sea surface and diving down to a maximum depth of 600 meters. 

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2. (2014) Coastal Endurance Array Mobile Assets (CE05MOAS)

   https://doi.org/10.58046/ooi-ce05moas  

   NSF_Ocean_Observatories_Initiative (January 2014, US NSF Ocean Observatories Initiative)

   An array of ~6 gliders travels along five east-west transect lines within the Coastal Endurance Array from approximately the 20-m isobaths to 126 W (and out to 128 W along the Oregon and Washington lines), as well as a north-south transect along 126 W. Coastal Gliders (Teledyne-Webb Slocum Gliders) fly through the water column along saw-tooth paths, penetrating the sea surface and diving down to depth. These Coastal Gliders are outfitted with one of two buoyancy engines allowing for maximum efficiency for either shallow (able to dive to 200 m) or deep (able to dive to 1000 m) dives. A roughly even combination of deep and shallow diving coastal gliders have been deployed, sufficient to survey the Endurance Array area. Gliders are buoyancy-driven mobile assets. They change their buoyancy by drawing in water through their nose making their front end heavy causing them to sink through the water. To float back up to the surface, they push the water out. Their wings provide lift allowing the gliders to move forward as they change depth. Due to their efficient design, with no need for propellers or an engine, gliders can be deployed for several months at a time. 

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3. (2024) Coastal Pioneer Mid-Atlantic Bight Mobile Asset Autonomous Underwater Vehicles (CP16MOAS)

   https://doi.org/10.58046/ooi-cp16moas  

   NSF_Ocean_Observatories_Initiative (January 2024, US NSF Ocean Observatories Initiative)

   Coastal Autonomous Underwater Vehicles (AUVs) are Mobile Assets that survey the area in and around the array of moorings at the Coastal Pioneer MAB Array. Two Coastal AUVs (HII REMUS-600 AUVs) travel along transects across the shelf-break frontal system extending beyond the mooring array, covering an area approximately 1000 square kilometers in size centered on the array of moorings. The primary role of the AUVs is to resolve cross- and along-front “eddy fluxes” due to frontal instabilities, wind forcing, and mesoscale variability. These AUVs travel along saw-toothed transects, penetrating the sea surface and diving down to a maximum depth of 600 meters. 

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4. Gulf Stream Near Cape Hatteras Modulates Sea Level Variability Along the Southeastern Coast of North America

   https://doi.org/10.1029/2024GL112776  

   Wu, Tianning; He, Ruoying (April 2025, Geophysical Research Letters)

   Abstract Studies suggest a strong link between low‐frequency sea level variability in the South Atlantic Bight (SAB) and open ocean dynamics. However, the mechanisms driving this connection remain unclear. By analyzing a high‐resolution, three‐dimensional baroclinic ocean reanalysis, we identify a pathway that links open ocean dynamics to SAB coastal sea level variability through the shelf edge near Cape Hatteras. Gulf Stream meanders in this region induce sea level fluctuations that propagate along the entire SAB shelf. Using an idealized barotropic model, we further demonstrate that topographic waves mediate the propagation of the Gulf Stream signal onto the shelf. Moreover, the Gulf Stream variability is driven by zonal wind stress in the Northwest Atlantic, which is likely modulated by the North Atlantic Oscillation. These findings offer new insights into regional sea level prediction and contribute to broader climate research efforts. 

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5. Gulf Stream Mean and Eddy Kinetic Energy: Three‐Dimensional Estimates From Underwater Glider Observations

   https://doi.org/10.1029/2020GL090281  

   Todd, Robert_E (March 2021, Geophysical Research Letters)

   Abstract The strong, meandering, and eddy‐shedding Gulf Stream is a large oceanic reservoir of both mean and eddy kinetic energy in the northwestern Atlantic. Since 2015, underwater gliders equipped with Doppler current profilers have collected over 20,000 absolute velocity profiles in and near the Gulf Stream along the US East Coast. Those observations are used to make three‐dimensional estimates of mean and eddy kinetic energy, substantially expanding the geographic coverage of prior estimates of subsurface kinetic energy in the Gulf Stream. Glider observations are combined via weighted least squares fitting with anisotropic and inhomogeneous length scales to reflect both circulation and sampling density; this averaging technique can be applied to other quantities measured by the gliders. Mean and eddy kinetic energy decay approximately exponentially away from the surface. Vertical decay scales are longest within the high‐speed core of the Gulf Stream and somewhat shorter on the flanks of the Gulf Stream. 

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