Multiple drivers of production and particle export in the western tropical North Atlantic

Korte, Laura F; Brummer, Geert-Jan A; Does, Michèlle van der; Guerreiro, Catarina; Mienis, Furu; Munday, Chris I; Ponsoni, Leandro; Schouten, Stefan; Stuut, Jan‐Berend

doi:10.1002/lno.11442

Cited by 14 publications

(19 citation statements)

References 78 publications

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“…Overall, the positive correlation between the UPZspp/LPZspp-CaCO 3 ratio and POC fluxes (Fig. 9d-all sites; Supplementary Table S7) reflects the enhanced coccolith-CaCO 3 production in the upper photic zone linked to higher productivity in shallower nutricline conditions, whether due to geostrophic wind forcing (i.e., sites CB and M1) or to the occurrence of transient surface blooms (site M4; see Guerreiro et al 2017Guerreiro et al , 2019Korte et al 2020).…”

Section: Coccolith-ballastingmentioning

confidence: 97%

“…This is also the case for the rare but very large-sized species Scyphosphaera apsteinii, included in the category "others," which produced up to 15 mg m À2 d À1 at site M4 (Supplementary Table S3). Still, and albeit their much lighter and smaller-sized coccoliths, G. flabellatus and F. profunda were the most important Korte et al 2017 andvan der Does et al 2020). The mass flux of unspecified particles (i.e., residual fraction) results from subtracting the weights of biogenic constituents (i.e., CaCO 3 , organic matter and biogenic silica) from the total mass and has been used as a proxy for dust deposition in the Atlantic Ocean (Jickells et al, 1998), including our study area (e.g., Fischer et al 2016;Guerreiro et al 2017;Korte et al 2017).…”

Section: Species Contributionsmentioning

confidence: 98%

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Carbonate fluxes by coccolithophore species between NW Africa and the Caribbean: Implications for the biological carbon pump

Guerreiro

Baumann

Brummer

et al. 2021

Limnology & Oceanography

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Coccolithophores are among the most important calcifying pelagic organisms. To assess how coccolithophore species with different coccolith-carbonate mass and distinct ecological resilience to ocean warming will influence the "rain ratio" and the "biological carbon pump", 1 yr of species-specific coccolith-carbonate export fluxes were quantified using sediment traps moored at four sites between NW Africa and the Caribbean (i.e., CB-20 N/21 W, at 1214 m; M1-12 N/23 W, at 1150 m; M2-14 N/37 W, at 1235 m; M4-12 N/49 W, at 1130 m). Highest coccolith-CaCO 3 fluxes at the westernmost site M4, where the nutricline is deepest along the tropical North Atlantic, were dominated by deep-dwelling small-sized coccolith species Florisphaera profunda and Gladiolithus flabellatus. Total coccolith-CaCO 3 fluxes of 371 mg m À2 yr À1 at M4 were followed by 165 mg m À2 yr À1 at the north-easternmost CB, 130 mg m À2 yr À1 at M1, and 114 mg m À2 yr À1 at M2 in between. Coccoliths accounted for nearly half of the total carbonate flux at M4 (45%), much higher compared to 23% at M2 and 15% at M1 and CB. At site M4, highest ratios of coccolith-CaCO 3 to particulate organic carbon fluxes and weak correlations between the carbonate of deep-dwelling species and particulate organic carbon suggest that increasing productivity in the lower photic zone in response to ocean warming might enhance the rain ratio and reduce the coccolithballasting efficiency. The resulting weakened biological carbon pump could, however, be counterbalanced by increasing frequency of Saharan dust outbreaks across the tropical Atlantic, providing mineral ballast as well as nutrients to fuel fast-blooming and ballast-efficient coccolithophore species.

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Section: Coccolith-ballastingmentioning

confidence: 97%

Section: Species Contributionsmentioning

confidence: 98%

Carbonate fluxes by coccolithophore species between NW Africa and the Caribbean: Implications for the biological carbon pump

Guerreiro

Baumann

Brummer

et al. 2021

Limnology & Oceanography

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“…Particularly relevant is the role of diatoms. While we account for this in our parameterizations, we treat DDAs and normal diatoms the same way, even though DDAs have been hypothesized to be more efficient in this export (Korte et al., 2020). This means that we may tend to underestimate the contribution of DDAs to POM formation and EP.…”

Section: Caveats and Limitationsmentioning

confidence: 99%

The Impact of the Amazon on the Biological Pump and the Air‐Sea CO₂ Balance of the Western Tropical Atlantic

Louchard

Gruber

Münnich

2021

Global Biogeochemical Cycles

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The Amazon River strongly modifies the biogeochemistry of the Western Tropical Atlantic (WTA). To disentangle the different mechanisms driving these modifications, we conduct a series of modeling experiments with a high‐resolution regional ocean model (ROMS) coupled to a biogeochemical/ecological model (BEC) that we augmented to include Diatom‐Diazotroph‐Assemblages (DDAs). In our model, the Amazon River increases net primary production (NPP) in the WTA by almost 10%, exceeding the stimulation expected from the supplied inorganic nitrogen and phosphorus by a factor of two. This amplification is fueled by new nitrogen stemming from DDA‐driven N2 fixation in the plume region, supported, in part, by the consumption of riverine dissolved organic phosphorus. The vertical export of organic carbon is enhanced by a shift of the phytoplankton community toward diatoms induced by the large amount of Si(OH)4 delivered by the Amazon. These changes in NPP and export production induce a strong uptake of atmospheric CO2. In contrast, the remineralization of the river‐delivered terrestrial organic matter leads to a release of CO2 over the WTA, which is partially offset by a net uptake induced by the riverine dissolved inorganic carbon and alkalinity. Overall, the Amazon reduces the strong outgassing of the WTA in our simulations by more than 50%. Our study demonstrates how rivers modify the marine biological pump and the air‐sea CO2 fluxes in the downstream ocean through a myriad of cascading effects, highlighting the need to fully consider the land‐ocean aquatic continuum in the modeling of the Earth System.

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“…At the same time, the lower sediment traps tend to show higher fluxes than their upper counterpart during the same year (13M2, 13M4 and 14M4; Figure 3). For the sediment traps at M4, geochemical analyses revealed that lateral input of Amazon‐River sediments to the upper trap is minimal, if not absent (Van der Does, Pourmand, et al., 2018), while the lower trap at 13M5 was affected by downslope transport of sediment re‐suspended from the nearby Barbados margin, causing much higher deposition fluxes than expected for the overall downwind decreasing trend, including the large outlier in April 2013 (Figure 3; Korte et al., 2020).…”

Section: Resultsmentioning

confidence: 99%

Seasonality in Saharan Dust Across the Atlantic Ocean: From Atmospheric Transport to Seafloor Deposition

et al. 2021

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Saharan dust is transported in great quantities from the North African continent every year, most of which is deposited across the North Atlantic Ocean. This dust impacts regional and global climate by affecting the atmospheric radiation balance and altering ocean carbon budgets. However, little research has been carried out on time series of Saharan dust collected in situ across the open Atlantic. Here, we present a unique three‐year time series of Saharan dust along a trans‐Atlantic transect, sampled by moored surface buoys and subsurface sediment traps. Results show a good correlation between the particle‐size distributions of atmospheric dust and the lithogenic particles settling to the deep ocean floor, confirming the aeolian origin of the lithogenic particles intercepted by the subsurface sediment traps, even in the distal western part of the Atlantic Ocean. Dust from both dry and wet deposition as collected by the sediment traps, shows increased deposition fluxes and coarser grain size in summer and/or autumn that coincides with increased precipitation at the sampling sites as derived from satellite data. In contrast, both buoys that sampled dust during transport at sea level show little seasonal variation in both concentration and particle size, as the large amounts of dust transported in summer and early autumn at high altitudes are far above their sampling range. This implies that wet deposition in summer and autumn defines the typical seasonal trends of both the dust deposition flux and its particle‐size distribution observed in the sediment traps.

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Multiple drivers of production and particle export in the western tropical North Atlantic

Cited by 14 publications

References 78 publications

Carbonate fluxes by coccolithophore species between NW Africa and the Caribbean: Implications for the biological carbon pump

Carbonate fluxes by coccolithophore species between NW Africa and the Caribbean: Implications for the biological carbon pump

The Impact of the Amazon on the Biological Pump and the Air‐Sea CO₂ Balance of the Western Tropical Atlantic

Seasonality in Saharan Dust Across the Atlantic Ocean: From Atmospheric Transport to Seafloor Deposition

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Multiple drivers of production and particle export in the western tropical North Atlantic

Cited by 14 publications

References 78 publications

Carbonate fluxes by coccolithophore species between NW Africa and the Caribbean: Implications for the biological carbon pump

Carbonate fluxes by coccolithophore species between NW Africa and the Caribbean: Implications for the biological carbon pump

The Impact of the Amazon on the Biological Pump and the Air‐Sea CO2 Balance of the Western Tropical Atlantic

Seasonality in Saharan Dust Across the Atlantic Ocean: From Atmospheric Transport to Seafloor Deposition

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The Impact of the Amazon on the Biological Pump and the Air‐Sea CO₂ Balance of the Western Tropical Atlantic