Tracing the fate of seabird‐derived nitrogen in a coral reef using nitrate and coral skeleton nitrogen isotopes
Résumé
Seabirds transfer nutrients from the ocean to their nesting island, potentially altering nitrogen (N) cycling within adjacent terrestrial and marine ecosystems. Yet, the processes involved in seabird‐N transfer along the land–sea continuum remain elusive. Using δ 15 N and δ 18 O measurements of groundwater nitrate, we demonstrate the role of brackish groundwater located within a coral island's landmass as a major reservoir of nitrate (at millimolar levels). Nearly all of the total dissolved seabird‐derived N leaching into the groundwater (mostly ammonium and uric acid) is converted to nitrate by nitrification, as supported by the relatively low δ 18 O of the groundwater nitrate (3.97‰ ± 0.30‰). Comparison of nitrate δ 15 N and δ 18 O suggests that little denitrification takes place within the groundwater lens, implying that the high δ 15 N of groundwater nitrate (13.73‰ ± 0.05‰) derives from the high trophic position of seabirds and postdepositional processes that increase the δ 15 N of seabird excreta. Seawater and coral skeleton samples from a reef flat exposed to groundwater had higher δ 15 N values than at sites devoid of groundwater influence, indicating that the main source of N at the latter site was the Subtropical Upper Water, while the groundwater nitrate dominated the exposed reef flat N pool up to 200 m from shore. In addition, these results indicate that coral‐bound δ 15 N can detect seabird‐derived nitrate δ 15 N, raising opportunities to reconstruct historical seabird‐N inputs to coral reefs in relation to climatic and other changes, such as the introduction of invasive species.
Origine : Publication financée par une institution
licence : CC BY NC - Paternité - Pas d'utilisation commerciale
licence : CC BY NC - Paternité - Pas d'utilisation commerciale