Persistent Lagrangian Transport Patterns in the Northwestern Gulf of Mexico

Gough, Matt K.; Beron-Vera, F. J.; Olascoaga, M. J.; Sheinbaum, Julio; Jouanno, Julien; Duran, Rodrigo

doi:10.1175/jpo-d-17-0207.1

Cited by 41 publications

(44 citation statements)

References 35 publications

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“…The main feature is a medium-size LCE in the impact area with an intensified northward current traveling along the continental slope, thus forming a hook-like pattern in the northwestern portion of the WGoM (Duran et al, 2018). This anticyclonic gyre was detected with drifter trajectories by Hamilton et al (1999) and with altimetry by Hyunn and Hogan (2008), who associated the gyre with the topographic effect of the northwestern corner, which formed a semienclosed slope shape between 26-28°N and 94-96°W; additionally, the gyre was identified by climatological Lagrangian coherent structures (cLCSs) nearly year-round (Gough et al, 2019), thus demonstrating that the shelf is isolated from the circulation beyond the shelf break. The pattern was not visible at 200-m depth in the presence of cyclones formed by the current stream (offshore direction) of the northern portion of the LCE.…”

Section: Journal Of Geophysical Research: Oceansmentioning

confidence: 97%

Ocean Circulation in the Western Gulf of Mexico Using Self‐Organizing Maps

et al. 2019

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The ocean circulation in the western Gulf of Mexico is influenced by Loop Current eddies (LCEs), which affect the thermohaline structure and distribution of environmental variables as well as the design and management of offshore structures and maritime activities. In this study, we assess the ocean circulation and its variability by applying dual self‐organizing maps (SOMs) to a 20‐year data set (1993–2012) of salinity and currents at a depth of 200 m from a Hybrid Coordinate Ocean Model. The geospatial variability is characterized via a 7 × 7 SOM, which is further grouped into seven patterns, while the temporal variability is characterized as six distinct regions using a 2 × 3 SOM. The influence of LCEs on the upper slope occurs along the 200‐m isobath, a zone under constant pressure by strong currents from impacting eddies. The temporal pattern variability also reveals a clear zone of LCE impact on the continental slope (between latitudes 22°N and 25°N) and a dominant offshore transport pattern around latitudes 25°N to 26°N. A rectified wavelet power spectral analysis reveals a frequency of LCE impact oscillating around four to five months with an estimated ring lifespan of 1 year.

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Section: Journal Of Geophysical Research: Oceansmentioning

confidence: 97%

Ocean Circulation in the Western Gulf of Mexico Using Self‐Organizing Maps

et al. 2019

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“…Our observed panmictic migration pattern hypothesizes that multiple larval dispersal patterns may be effective to enable gene flow over time among all banks in the study. The LCC experiences seasonal variability, and in rarer cases, eastward transport following impingement on the continental shelf (Jarosz and Murray, 2005;Gough et al, 2017). The LCC may reverse direction during summer months (June-August) and flow eastward at a weaker speed.…”

Section: Depth Meso Shallowmentioning

confidence: 99%

“…Most of these habitats are at mesophotic depths (∼30-150 m), but notably West and East Flower Garden Banks (FGB), approximately 180 km from the Texas coast, also have relatively shallow coral reef habitats from 17 to 30 m. While at higher latitudes than most other reefs in the Tropical Western Atlantic (TWA) and therefore spatially isolated, coral populations in the NW GOM are thought to persist due to thermal stability and relatively high larval dispersal potential from the Gulf of Mexico Loop Current (Oey et al, 2005;Atchison et al, 2008;Nunes et al, 2011;Precht et al, 2014;Rippe et al, 2017). Westward-moving eddy formations and coastal currents are also quite common in the NW GOM and may connect reef populations along the continental margin (Ohlmann and Niiler, 2005;Schmahl et al, 2008;Gough et al, 2017). Despite residing at sub-tropical latitudes, reefs in the NW GOM have relatively stable seasonal temperatures between 18 and 30 • C due to persistence of currents, and major coral bleaching events are rare (Rezak et al, 1990;Schmahl et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Assessment of Mesophotic Coral Ecosystem Connectivity for Proposed Expansion of a Marine Sanctuary in the Northwest Gulf of Mexico: Population Genetics

Studivan

Voss

2018

Front. Mar. Sci.

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“…The assessment of motions of floating matter in the ocean is of importance for a number of key reasons. These range from improving search-and-rescue operations at sea 1,2 ; to better understanding the drift of flotsam of different nature including macroalgae such as Sargassum [3][4][5] , plastic litter 6,7 , airplane wreckage 8,9 , tsunami debris 10,11 , sea-ice pieces 12 , larvae 13,14 , and oil 15,16 ; to better interpreting "Lagrangian" observations in the ocean 17,18 . At present, largely piecemeal, ad-hoc approaches are taken to simulate the effects of ocean currents and winds on the drift of floating objects.…”

Section: Introductionmentioning

confidence: 99%

Observation and quantification of inertial effects on the drift of floating objects at the ocean surface

et al. 2020

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We present results from an experiment designed to better understand the mechanism by which ocean currents and winds control flotsam drift. The experiment consisted in deploying in the Florida Current and subsequently satellite tracking specially designed drifting buoys of varied sizes, buoyancies, and shapes. We explain the differences in the trajectories described by the special drifters as a result of their inertia, primarily buoyancy, which constrains the ability of the drifters to adapt their velocities to instantaneous changes in the ocean current and wind that define the carrying flow field. Our explanation of the observed behavior follows from the application of a recently proposed Maxey-Riley theory for the motion of finite-size particles floating at the surface ocean. The nature of the carrying flow and the domain of validity of the theory are clarified, and a closure proposal is made to fully determine its parameters in terms of the carrying fluid system properties and inertial particle characteristics.

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Persistent Lagrangian Transport Patterns in the Northwestern Gulf of Mexico

Cited by 41 publications

References 35 publications

Ocean Circulation in the Western Gulf of Mexico Using Self‐Organizing Maps

Ocean Circulation in the Western Gulf of Mexico Using Self‐Organizing Maps

Assessment of Mesophotic Coral Ecosystem Connectivity for Proposed Expansion of a Marine Sanctuary in the Northwest Gulf of Mexico: Population Genetics

Observation and quantification of inertial effects on the drift of floating objects at the ocean surface

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