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Observation-Based Resource Assessment of Gulf Stream MHK

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Multi-year measurements of current velocity, salinity, and temperature from fixed and vessel-mounted sensors quantify Gulf Stream (GS) MHK resource variability and inform development off Cape Hatteras, NC. Vessel transects across the GS demonstrate a jet-like velocity structure with speeds exceeding 2.5 m/s at the surface, persistent horizontal shear throughout the jet, and strongest vertical shears within the cyclonic shear zone. Persistent equatorward flow at the base of the GS associated with the Deep Western Boundary Current (DWBC) produces a local maximum in vertical shear where stratification is weak and is postulated to be a site of strong turbulent mixing. Repeated transects at the same location demonstrate that the velocity structure depends upon whether the GS abuts the shelf slope or is offshore.

Citation Formats

North Carolina State University. (2020). Observation-Based Resource Assessment of Gulf Stream MHK [data set]. Retrieved from https://mhkdr.openei.org/submissions/347.
Export Citation to RIS
Muglia, Michael, Seim, Harvey, and Taylor, Patterson. Observation-Based Resource Assessment of Gulf Stream MHK. United States: N.p., 01 Jan, 2020. Web. https://mhkdr.openei.org/submissions/347.
Muglia, Michael, Seim, Harvey, & Taylor, Patterson. Observation-Based Resource Assessment of Gulf Stream MHK. United States. https://mhkdr.openei.org/submissions/347
Muglia, Michael, Seim, Harvey, and Taylor, Patterson. 2020. "Observation-Based Resource Assessment of Gulf Stream MHK". United States. https://mhkdr.openei.org/submissions/347.
@div{oedi_4029, title = {Observation-Based Resource Assessment of Gulf Stream MHK}, author = {Muglia, Michael, Seim, Harvey, and Taylor, Patterson.}, abstractNote = {Multi-year measurements of current velocity, salinity, and temperature from fixed and vessel-mounted sensors quantify Gulf Stream (GS) MHK resource variability and inform development off Cape Hatteras, NC. Vessel transects across the GS demonstrate a jet-like velocity structure with speeds exceeding 2.5 m/s at the surface, persistent horizontal shear throughout the jet, and strongest vertical shears within the cyclonic shear zone. Persistent equatorward flow at the base of the GS associated with the Deep Western Boundary Current (DWBC) produces a local maximum in vertical shear where stratification is weak and is postulated to be a site of strong turbulent mixing. Repeated transects at the same location demonstrate that the velocity structure depends upon whether the GS abuts the shelf slope or is offshore.}, doi = {}, url = {https://mhkdr.openei.org/submissions/347}, journal = {}, number = , volume = , place = {United States}, year = {2020}, month = {01}}

Details

Data from Jan 1, 2020

Last updated Jan 14, 2021

Submitted Dec 4, 2020

Organization

North Carolina State University

Contact

Chris Vermillion

919.515.5244

Authors

Michael Muglia

East Carolina University

Harvey Seim

University of North Carolina at Chapel Hill

Patterson Taylor

East Carolina University

DOE Project Details

Project Name Device Design and Robust Periodic Motion Control of an Ocean Kite System for Marine Hydrokinetic Energy Harvesting

Project Lead Carrie Noonan

Project Number EE0008635

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