Salinity variability along the eastern continental shelf of Canada and the United States, 1973–2013

Bisagni, James J.

doi:10.1016/j.csr.2016.08.003

Cited by 11 publications

(8 citation statements)

References 60 publications

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“…4 509 511 513 515 517 519 521 523 525 527 529 531 533 535 537 539 541 543 545 547 549 551 553 555 557 559 561 563 565 567 IAV of LC transport at the shelf break along segment 191SW near 52° W from this study 581 is large (Fig. 4), with a strong negative (positive) transport anomaly corresponding to strong 582 positive (negative) salinity anomalies as shown by other studies for 1996 and 1997, (Rossby and 583 Benway, 2000; Flagg et al, 2006;Bisagni, 2016). Sea surface height along ground track segment 584 250 is chosen as representative of upstream LC transport within the Labrador Sea.…”

Section: Gulf Stream North Wall (Gsnw) Analysis 235supporting

confidence: 56%

Secular change and inter-annual variability of the Gulf Stream position, 1993–2013, 70°−55°W

Bisagni

Gangopadhyay

Sanchez-Franks

2017

Deep Sea Research Part I: Oceanographic Research Papers

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21The Gulf Stream (GS) is the northeastward-flowing surface limb of the Atlantic Ocean's 22 meridional overturning circulation (AMOC) "conveyer belt" that flows towards Europe and the 23 Nordic Seas. Changes in the GS position after its separation from the coast at Cape Hatteras, i.e., 24 from 75°W to 50°W, may be key to understanding the AMOC, sea level variability and 25 ecosystem behavior along the east coast of North America. In this study we compare secular 26 change and inter-annual variability (IAV) of the Gulf Stream North Wall (GSNW) position with 27 equator-ward Labrador Current (LC) transport along the southwestern Grand Banks near 52° W 28 using 21 years of satellite altimeter data. Results at 55°, 60°, and 65° W show a 29 significant southward (negative) secular trend for the GSNW, decreasing to a small but 30 insignificant southward trend at 70° W. IAV of de-trended GSNW position residuals also 31 decreases to the west. The long-term secular trend of annual mean upper layer (200 m) LC 32 transport near 52° W is positive. Furthermore, IAV of LC transport residuals near 52° W along 33 the southwestern Grand Banks are significantly correlated with GSNW position residuals at 55° 34 W at a lag of +1-year, with positive (negative) LC transport residuals corresponding to 35 southward (northward) GSNW positions one year later. The Taylor-Stephens index (TSI) 36 computed from the first principal component of the GSNW position from 79° to 65° W shows a 37 similar relationship with a more distal LC index computed along altimeter ground track 250 38 located north of the Grand Banks across Hamilton Bank in the western Labrador Sea. Increased 39 (decreased) sea height differences along ground track 250 are significantly correlated with a 40 more southward (northward) TSI two years later (lag of +2-years). Spectral analysis of IAV 41 reveals corresponding spectral peaks at 5-7 years and 2-3 years for the North Atlantic Oscillation 42 (NAO), GSNW (70°-55°W) and LC transport near 52° W for the 1993-2013 period suggesting a 43 connection between these phenomena. An upper-layer (200 m) slope water volume calculation 44 using the LC IAV rms residual of +1.04 Sv near 52° W results in an estimated GSNW IAV 45 residual of 79 km, or 63% of the observed 125.6 km (1.13°) rms value at 55° W. A similar 46 upper-layer slope water volume calculation using the positive long-term, upper-layer LC 47 transport trend accounts for 68% of the mean observed secular southward shift of the GSNW 48 between 55° and 70°W over the 1993-2013 period. Our work provides additional observational 49 evidence of important interactions between the upper layers of the sub-polar and sub-tropical 50 gyres within the North Atlantic over both secular and inter-annual time scales as suggested by 51 previous studies. 52 53

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Section: Gulf Stream North Wall (Gsnw) Analysis 235supporting

confidence: 56%

Secular change and inter-annual variability of the Gulf Stream position, 1993–2013, 70°−55°W

Bisagni

Gangopadhyay

Sanchez-Franks

2017

Deep Sea Research Part I: Oceanographic Research Papers

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“…In addition to the consistent seasonal and daily patterns of some environmental factors, the marine organisms are also under the effect of fluctuating factors, such as seawater temperature 14 and salinity 15 , which might vary with wind conditions over short periods. Temperature is one of the most important factors influencing all biological activities 16 and, in particular, ectothermic organisms, such as fish, can tolerate a very narrow range of temperature.…”

Section: Introductionmentioning

confidence: 99%

Seasonal influence on the bathymetric distribution of an endangered fish within a marine protected area

Brazo

Marques

Zimmermann

et al. 2021

Sci Rep

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The spatio-temporal variability of fish distribution is important to better manage and protect the populations of endangered species. In this sense, the vertical movements of a vulnerable and protected species, Sciaena umbra, were assessed in a marine protected area (the Réserve Naturelle Marine de Cerbère-Banyuls, south of France) to study the variability of their bathymetric distribution at different time scales. Twenty adults were marked with acoustic transmitters and acoustically monitored over 2.5 years. This revealed that some individuals remained at shallow waters (< 8 m) all year round, while others presented vertical segregation at deeper waters during the cold months (mean depth of 22.5 ± 0.04 m) and all aggregated in shallow waters during the warm months. The brown meagre was more active during the night, except in June and July when peaks of activity were observed at dusk. These patterns are likely associated with foraging and reproductive behavior during the cold and warm periods, respectively, and likely regulated by water temperature and the depth of the thermocline. Here, we provide valuable information on when and where in the water column critical periods of S. umbra life cycle are expected to occur, which should be considered in management and protection plans.

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“…Only a limited number of climatologies have been constructed specifically for shelf areas, e.g. for the eastern seaboard of North America (Atkinson et al, 1983;Blanton et al, 2003;Bisagni, 2016;Richaud et al, 2016) and the Ross Sea off Antarctica (Russo et al, 2011). Most climatologies of key ocean variables exclude data from "land grid-boxes", i.e.…”

Section: Introductionmentioning

confidence: 99%

Temperature, Salinity and Oxygen Climatology of African Continental Shelf Water, South of the Equator, and Changes Since 1945

Villiers¹

2021

Preprint

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The first temperature, salinity and oxygen climatologies for waters of the continuous southern African continental shelf is presented. It is based on oceanographic data collected since 1945, sub-sampled at depths of 5, 50 and 100 m on a mixed-spatial grid with 0.25° to 0.5° resolution. The climatologies capture spatial heterogeneities and seasonal variability in key ocean variables for the southern African shelf in unique detail. The results correspond relatively well with biogeographic boundaries informed by classification schemes grounded in taxonomy, but questions the value of the Large Marine Ecosystem approach. Analysis of decadal trends demonstrates the inherent complexity and spatial heterogeneity associated with environmental variability, and suggest the possibility that decadal periodicities are in the process of being disrupted by a longer-term trend. The overall pattern is that southern African West and South coast shelf waters are becoming warmer, except for some upwelling areas, where cooling is evident. Benguela and Agulhas Bank shelf water are also becoming more oxygen depleted.

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Salinity variability along the eastern continental shelf of Canada and the United States, 1973–2013

Cited by 11 publications

References 60 publications

Secular change and inter-annual variability of the Gulf Stream position, 1993–2013, 70°−55°W

Secular change and inter-annual variability of the Gulf Stream position, 1993–2013, 70°−55°W

Seasonal influence on the bathymetric distribution of an endangered fish within a marine protected area

Temperature, Salinity and Oxygen Climatology of African Continental Shelf Water, South of the Equator, and Changes Since 1945

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