4.7 Article

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

期刊

LIMNOLOGY AND OCEANOGRAPHY
卷 66, 期 8, 页码 3190-3208

出版社

WILEY
DOI: 10.1002/lno.11872

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资金

  1. NWO [822.01.008]
  2. ERC [311152]
  3. UniBremen
  4. EU FP7 COFUND [600411]
  5. Marie Sklodowska-Curie European Fellowship - EU H2020-MSCA-IF-2017 within DUSTCO [796802]
  6. FCT [CEECIND/00752/2018/CP1534/CT0011]
  7. PORTWIMS - EU's H2020 Research and Innovation Programme [810139]
  8. ERDF of the INTERREG Atlantic Area Programme [EAPA-165/2016]
  9. CALMED [CTM2016-79547-R]
  10. Generalitat de Catalunya MERS [2017 SGR-1588]
  11. Marie Curie Actions (MSCA) [796802] Funding Source: Marie Curie Actions (MSCA)
  12. Fundação para a Ciência e a Tecnologia [CEECIND/00752/2018/CP1534/CT0011] Funding Source: FCT
  13. European Research Council (ERC) [311152] Funding Source: European Research Council (ERC)

向作者/读者索取更多资源

Coccolithophores play a significant role in the biological carbon pump. Different species of coccolithophores at different sites show variations in coccolith-carbonate flux, influenced by environmental factors such as nutrient availability and temperature. The study suggests that changes in productivity in response to ocean warming may affect the efficiency of the biological carbon pump.
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 degrees N/21 degrees W, at 1214 m; M1-12 degrees N/23 degrees W, at 1150 m; M2-14 degrees N/37 degrees W, at 1235 m; M4-12 degrees N/49 degrees W, at 1130 m). Highest coccolith-CaCO3 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-CaCO3 fluxes of 371 mg m(-2) yr(-1) at M4 were followed by 165 mg m(-2) yr(-1) at the north-easternmost CB, 130 mg m(-2) yr(-1) at M1, and 114 mg m(-2) yr(-1) 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-CaCO3 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 coccolith-ballasting 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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