Disentangling the impact of nutrient load and climate changes on Baltic Sea hypoxia and eutrophication since 1850

In the Baltic Sea hypoxia has been increased considerably since the first oxygen measurements became available in 1898. In 2016 the annual maximum extent of hypoxia covered an area of the sea bottom of about 70,000 km 2 , comparable with the size of Ireland, whereas 150 years ago hypoxia was presuma...

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Bibliographic Details
Published in:Climate dynamics 2019-07, Vol.53 (1-2), p.1145-1166
Main Authors: Meier, H. E. M., Eilola, K., Almroth-Rosell, E., Schimanke, S., Kniebusch, M., Höglund, A., Pemberton, P., Liu, Y., Väli, G., Saraiva, S.
Format: Article
Language:English
Subjects:
Air temperature
Anthropogenic factors
Atmospheric pollution deposition
Biogeochemistry
Climate
Climate change
Climatic changes
Climatology
Cloud cover
Cloudiness
Earth and Environmental Science
Earth Sciences
Ecosystems
Environmental aspects
Eustatic changes
Eutrophication
Geophysics/Geodesy
Global warming
Human influences
Hypoxia
Hypoxia (Aquatic ecology)
Loads (forces)
Mineral nutrients
Mixed layer
Mixed layer depth
Nutrient concentrations
Nutrient loading
Ocean circulation
Ocean currents
Ocean models
Oceanography
Oxygen
Sea level
Sea level rise
Water circulation
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Summary:In the Baltic Sea hypoxia has been increased considerably since the first oxygen measurements became available in 1898. In 2016 the annual maximum extent of hypoxia covered an area of the sea bottom of about 70,000 km 2 , comparable with the size of Ireland, whereas 150 years ago hypoxia was presumably not existent or at least very small. The general view is that the increase in hypoxia was caused by eutrophication due to anthropogenic riverborne nutrient loads. However, the role of changing climate, e.g. warming, is less clear. In this study, different causes of expanding hypoxia were investigated. A reconstruction of the changing Baltic Sea ecosystem during the period 1850–2008 was performed using a coupled physical-biogeochemical ocean circulation model. To disentangle the  drivers of eutrophication and hypoxia a series of sensitivity experiments was carried out. We found that the decadal to centennial changes in eutrophication and hypoxia were mainly caused by changing riverborne nutrient loads and atmospheric deposition. The impacts of other drivers like observed warming and eustatic sea level rise were comparatively smaller but still important depending on the selected ecosystem indicator. Further, (1) fictively combined changes in air temperature, cloudiness and mixed layer depth chosen from 1904, (2) exaggerated increases in nutrient concentrations in the North Sea and (3) high-end scenarios of future sea level rise may have an important impact. However, during the past 150 years hypoxia would not have been developed if nutrient conditions had remained at pristine levels.
ISSN:0930-7575
1432-0894
DOI:10.1007/s00382-018-4296-y