Physical drivers of pelagic sargassum bloom interannual variability in the Central West Atlantic over 2010–2020

Since 2011, unprecedented pelagic sargassum seaweed blooms have occurred across the tropical North Atlantic, with severe socioeconomic impacts for coastal populations. To investigate the role of physical drivers in post-2010 sargassum blooms in the Central West Atlantic (CWA), conditions are examine...

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Bibliographic Details
Published in:Ocean dynamics 2022-06, Vol.72 (6), p.383-404
Main Authors: Skliris, Nikolaos, Marsh, Robert, Appeaning Addo, Kwasi, Oxenford, Hazel
Format: Article
Language:English
Subjects:
Algae
Atmospheric Sciences
Blooms
Convergence
Convergence zones
Earth and Environmental Science
Earth Sciences
Equatorial upwelling
Fluid- and Aerodynamics
Geophysics/Geodesy
Interannual variability
Intertropical convergence zone
Maximum winds
Mineral nutrients
Monitoring/Environmental Analysis
Natural variability
Nutrient transport
Nutrients
Ocean circulation
Oceanography
River plumes
Seasonal variations
Seasonality
Seaweeds
Trade winds
Transport
Tropical climate
Upwelling
Variability
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Summary:Since 2011, unprecedented pelagic sargassum seaweed blooms have occurred across the tropical North Atlantic, with severe socioeconomic impacts for coastal populations. To investigate the role of physical drivers in post-2010 sargassum blooms in the Central West Atlantic (CWA), conditions are examined across the wider tropical North Atlantic, using ocean and atmospheric re-analyses and satellite-derived datasets. Of particular consequence for the growth and drift of sargassum are patterns and seasonality of winds and currents. Results suggest that in years of exceptionally large sargassum blooms (2015, 2018), the Intertropical Convergence Zone (ITCZ), an area of maximum wind convergence where sargassum naturally accumulates, shifted southward, towards nutrient-rich waters of the Amazon River plume and the equatorial upwelling zone further stimulating sargassum growth. These changes are associated with modes of natural variability in the tropical Atlantic, notably a negative phase of the Atlantic Meridional Mode (AMM) in 2015 and 2018, and a positive phase of the Atlantic Niño in 2018. Negative AMM in these 2 years is also associated with stronger trade winds and enhanced northwest Africa upwelling, probably resulting in stronger southwestward nutrient transport into the eastern part of CWA. Moreover, in contrast with most years, important secondary winter blooms took place in both 2015 and 2018 in the northern part of CWA, associated with excessive wind-driven equatorial upwelling and anomalously strong northwestward nutrient transport.
ISSN:1616-7341
1616-7228
DOI:10.1007/s10236-022-01511-1