From nitrogen enrichment to oxygen depletion: a mechanistic model of coastal marine ecosystems response ...

No abstracts are to be cited without prior reference to the author.Nitrogen (N) emissions from anthropogenic sources may enrich coastal waters and lead to marine eutrophication impacts. Processes describing N-limited primary production (PP), zooplankton grazing, and bacterial respiration of sinking...

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Bibliographic Details
Main Authors: Cosme, Nuno, Koski, Marja, Hauschild, Michael Zwicky
Format: Conference Object
Language:unknown
Published: ASC 2015 - Theme session R 2024
Subjects:
Online Access:https://dx.doi.org/10.17895/ices.pub.25682694.v1
https://ices-library.figshare.com/articles/conference_contribution/From_nitrogen_enrichment_to_oxygen_depletion_a_mechanistic_model_of_coastal_marine_ecosystems_response/25682694/1
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Summary:No abstracts are to be cited without prior reference to the author.Nitrogen (N) emissions from anthropogenic sources may enrich coastal waters and lead to marine eutrophication impacts. Processes describing N-limited primary production (PP), zooplankton grazing, and bacterial respiration of sinking organic carbon, were modelled to quantify the potential dissolved oxygen (DO) consumption as a function of N input. Such indicator is the basis for an eXposure Factor (XF) applied in Life Cycle Impact Assessment (LCIA) to estimate impacts from N enrichment. The Large Marine Ecosystems (LME) biogeographical classification system was adopted to address the spatial variation of the modelled parameters and to characterise spatially differentiated N-emissions. Preliminary XF results range from 0.5 kgO2·kgN-1 in the Central Arctic Ocean to 16 kgO2·kgN-1 in the Baltic Sea, out of a total of 66 LME-dependent XFs. All the relevant processes were included in a mechanistic model and the uncertainty of the driving parameters ...