Abstract
The northern Gulf of Mexico (GoM) is a region strongly influenced by river discharges of freshwater and nutrients, which promote a highly productive coastal ecosystem that host commercially valuable marine species. A variety of climate and weather processes could potentially influence the river discharges into the northern GoM. However, their impacts on the coastal ecosystem remain poorly described. By using a regional ocean-biogeochemical model, complemented with satellite and in situ observations, here we show that El Niño - Southern Oscillation (ENSO) is a main driver of the interannual variability in salinity and plankton biomass during winter and spring. Composite analysis of salinity and plankton biomass anomalies shows a strong asymmetry between El Niño and La Niña impacts, with much larger amplitude and broader areas affected during El Niño conditions. Further analysis of the model simulation reveals significant coastal circulation anomalies driven by changes in salinity and winds. The coastal circulation anomalies in turn largely determine the spatial extent and distribution of the ENSO-induced plankton biomass variability. These findings highlight that ENSO-induced changes in salinity, plankton biomass, and coastal circulation across the northern GoM are closely interlinked and may significantly impact the abundance and distribution of fish and invertebrates.
Highlights
The strongest ENSO anomalies in river discharge, salinity and plankton biomass occur during winter and early spring, while conditions for the development of bottom hypoxia appear to occur mainly during late spring and early summer41,43
We performed Empirical Orthogonal Function (EOF) decomposition52 to extract the main mode of interannual variability in surface anomalies of salinity, plankton biomass, and chlorophyll
The definition of the El Niño/La Niña periods was based on the Niño 3.4 region (N34) time series, with warm ENSO conditions linked to N34 values > 0.5 °C (
Summary
Our model results provide a framework to better comprehend ENSO-related variability in the northern GoM ecosystem and advance understanding of the larger-scale climate variability mode as a driver of ecosystem and marine population changes. ENSO-induced anomalies in river discharge, phytoplankton biomass, and winds could potentially influence hypoxia development over the Louisiana-Texas shelf41,42. The strongest ENSO anomalies in river discharge, salinity and plankton biomass occur during winter and early spring, while conditions for the development of bottom hypoxia appear to occur mainly during late spring and early summer41,43.
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