Drivers and impact of the seasonal variability of the organic carbon offshore transport in the Canary upwelling system

Abstract: Abstract. The Canary upwelling system (CanUS) is a productive coastal region characterized by strong seasonality and an intense offshore transport of organic carbon (Corg) to the adjacent oligotrophic offshore waters. There, the respiration of this Corg substantially modifies net community production (NCP). While this transport and the resulting coupling of the biogeochemistry between the coastal and open ocean has been well studied in the annual mean, the temporal variability, and especially its seasonality, … Show more

“…In the case of the vertical advective fluxes, their smaller absolute magnitude in the core of AEs is largely due to the depletion of DIN in the euphotic zone of AEs. This is possibly partially associated with a southward drift of the AE (Figure 2) towards regions of less negative wind stress curl (Bonino et al., 2021). In fact, the net contribution of vertical advection in AE cores is not negative at all times, showing a substantially more noisy and vacillating contribution to the budget at most stages of the eddy life, compared to CEs.…”

“…An Eulerian analysis of the same model run adopted in this study highlighted seasonal variations in the rates of production in the core of the eddies of the CanUS (Bonino et al., 2021). These result from a combination of factors among which large scale temporal variations in vertical fluxes of nutrients, the seasonality of upwelling and the eddy distance from the coast.…”

“…Tracer patterns in the AEs of the northern CanUS, instead, are strongly influenced by the lateral stirring of the large scale regional gradient, especially due to the southern drift of AE tracks, which approach the biophysical boundary of the Cape Verde front. This front, in fact, separates the nutrient‐depleted offshore waters of the open North Atlantic Subtropical Gyre from the region of the North Atlantic Tropical circulation, characterized by the DIN rich South Atlantic Central Water and by a positive wind‐stress curl fueling organic matter production also offshore (Arístegui et al., 2009; Bonino et al., 2021). Through this lateral stirring, AEs have therefore an important role in shaping the large scale DIN and PON distribution of the region, laterally coupling the subtropical and tropical regions of the CanUS located respectively north and south of the Cape Verde front.…”

“…On the other side, the large scale negative signature of the wind stress curl in the CanUS leads to a downward Ekman pumping (Pelegrí & Benazzouz, 2015). This large scale downwelling flux is especially important in CEs, which tend to drift northwards (Figure 2) toward the areas with the most negative wind stress curl (Bonino et al, 2021).…”

On the Processes Sustaining Biological Production in the Offshore Propagating Eddies of the Northern Canary Upwelling System

“…In the case of the vertical advective fluxes, their smaller absolute magnitude in the core of AEs is largely due to the depletion of DIN in the euphotic zone of AEs. This is possibly partially associated with a southward drift of the AE (Figure 2) towards regions of less negative wind stress curl (Bonino et al., 2021). In fact, the net contribution of vertical advection in AE cores is not negative at all times, showing a substantially more noisy and vacillating contribution to the budget at most stages of the eddy life, compared to CEs.…”

“…An Eulerian analysis of the same model run adopted in this study highlighted seasonal variations in the rates of production in the core of the eddies of the CanUS (Bonino et al., 2021). These result from a combination of factors among which large scale temporal variations in vertical fluxes of nutrients, the seasonality of upwelling and the eddy distance from the coast.…”

“…Tracer patterns in the AEs of the northern CanUS, instead, are strongly influenced by the lateral stirring of the large scale regional gradient, especially due to the southern drift of AE tracks, which approach the biophysical boundary of the Cape Verde front. This front, in fact, separates the nutrient‐depleted offshore waters of the open North Atlantic Subtropical Gyre from the region of the North Atlantic Tropical circulation, characterized by the DIN rich South Atlantic Central Water and by a positive wind‐stress curl fueling organic matter production also offshore (Arístegui et al., 2009; Bonino et al., 2021). Through this lateral stirring, AEs have therefore an important role in shaping the large scale DIN and PON distribution of the region, laterally coupling the subtropical and tropical regions of the CanUS located respectively north and south of the Cape Verde front.…”

“…On the other side, the large scale negative signature of the wind stress curl in the CanUS leads to a downward Ekman pumping (Pelegrí & Benazzouz, 2015). This large scale downwelling flux is especially important in CEs, which tend to drift northwards (Figure 2) toward the areas with the most negative wind stress curl (Bonino et al, 2021).…”

On the Processes Sustaining Biological Production in the Offshore Propagating Eddies of the Northern Canary Upwelling System

“…Uncertainties in the future of productivity, combined with uncertainties in ecosystem shifts induced by changes in temperature, acidity, and oxygenation, imply crucial uncertainties in the future of organic carbon export and sequestration in EBUS regions. This uncertainty further extends to the adjacent open basins, which receive and export significant amounts of coastally produced carbon (Bonino et al 2021), highlighting how understanding the future of EBUSs is key to refining projections of the organic carbon cycle on larger scales.…”

Climate Change Impacts on Eastern Boundary Upwelling Systems

Outgassing of CO2 dominates in the coastal upwelling off the northwest African coast