Project Details
Metabolism of Nitrogen in the Amazon River plume and Western Tropical North Atlantic (MeNARP)
Applicants
Dr. Natalie Loick-Wilde; Professorin Dr. Maren Voß
Subject Area
Oceanography
Animal Physiology and Biochemistry
Ecology and Biodiversity of Animals and Ecosystems, Organismic Interactions
Animal Physiology and Biochemistry
Ecology and Biodiversity of Animals and Ecosystems, Organismic Interactions
Term
from 2020 to 2024
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 439440452
Estuaries critically control how much of allochthonous nutrients from rivers reach the open ocean and how much carbon dioxide can be sequestered in the river plume. The Amazon River contributes nearly one fifth of the global riverine freshwater input to the ocean and is fed by the largest drainage basin in the world. The outflow of water and nutrients into the tropical Atlantic and Caribbean Sea has recently been linked to massive blooms of Sargassum in these areas. However, the role of allochthonous nutrients for the production along the plume is still unclear. Discordant lines of evidence suggest that all or none of the nutrients reach the open ocean. Light availability and inorganic and organic nitrogen compounds seem to control the production of photo- and heterotrophs - here summarized as trophic functional groups (TFGs). From recent studies it is possible to identify three different habitats along the plume; the estuary, the mesohaline and oceanic region. The MeNARP project wants to identify and quantify the metabolism of inorganic and organic nitrogen compounds and their role in shaping the TFGs. During an approved Meteor cruise the plume structure and mixing will be studied by a combination of measurements with standard CTD casts, microstructure profiler, current meters and drifter buoy. These data and satellite images will identify the habitat types where additional sampling and experiments will be carried out. Process stations where only basic variables will be measured deliver the hydrographic context, at biogeochemical stations samples for numerous stable isotope data will be gathered and at four long-term experimental stations numerous microbial rates will also be measured. The ultimate goal is to generate a data based characterization of the habitats along the plume to improve estimations of carbon sequestration and N export by means of a biogeochemical model developed in close cooperation with partners of the project.
DFG Programme
Research Grants
Co-Investigator
Dr. Volker Mohrholz