Coupling of oceanic carbon and nitrogen facilitates spatially resolved quantitative reconstruction of nitrate inventories

Anthropogenic impacts are perturbing the global nitrogen cycle via warming effects and pollutant sources such as chemical fertilizers and burning of fossil fuels. Understanding controls on past nitrogen inventories might improve predictions for future global biogeochemical cycling. Here we show the...

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Bibliographic Details
Published in:Nature communications 2018-03, Vol.9 (1), p.1217-10, Article 1217
Main Authors: Glock, Nicolaas, Erdem, Zeynep, Wallmann, Klaus, Somes, Christopher J., Liebetrau, Volker, Schönfeld, Joachim, Gorb, Stanislav, Eisenhauer, Anton
Format: Article
Language:English
Subjects:
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Anthropogenic factors
Biogeochemistry
Bottom water
Burning
Carbon cycle
Chemical pollution
Deglaciation
Fertilizers
Fossil fuels
Holocene
Human influences
Humanities and Social Sciences
Inventories
multidisciplinary
Nitrates
Nitrogen
Nitrogen cycle
Ocean models
Pollutants
Pollution sources
Reconstruction
Science
Science (multidisciplinary)
Three dimensional models
Upwelling
Water column
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Summary:Anthropogenic impacts are perturbing the global nitrogen cycle via warming effects and pollutant sources such as chemical fertilizers and burning of fossil fuels. Understanding controls on past nitrogen inventories might improve predictions for future global biogeochemical cycling. Here we show the quantitative reconstruction of deglacial bottom water nitrate concentrations from intermediate depths of the Peruvian upwelling region, using foraminiferal pore density. Deglacial nitrate concentrations correlate strongly with downcore δ 13 C, consistent with modern water column observations in the intermediate Pacific, facilitating the use of δ 13 C records as a paleo-nitrate-proxy at intermediate depths and suggesting that the carbon and nitrogen cycles were closely coupled throughout the last deglaciation in the Peruvian upwelling region. Combining the pore density and intermediate Pacific δ 13 C records shows an elevated nitrate inventory of >10% during the Last Glacial Maximum relative to the Holocene, consistent with a δ 13 C-based and δ 15 N-based 3D ocean biogeochemical model and previous box modeling studies. Understanding controls on past nitrogen budgets can improve predictions for future global biogeochemical cycling. Here, using foraminiferal pore density and δ 13 C, the authors present a quantitative record of deglacial nitrate from the intermediate Pacific and infer close coupling between carbon and nitrogen cycles.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-018-03647-5