Legacy‐micropollutant contamination levels in major river basins based on findings from the Rhône Sediment Observatory

For more than half a century, chemical contamination has progressively spread to all the large river basins. Large river outlets integrate multiple anthropogenic pressures in watersheds, making them the largest source of sediment‐bound contaminants to continental shelf areas. However, comparing part...

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Bibliographic Details
Published in:Hydrological processes 2022-02, Vol.36 (2), p.n/a
Main Authors: Delile, Hugo, Dendievel, André‐Marie, Yari, Anice, Masson, Matthieu, Miège, Cécile, Mourier, Brice, Coquery, Marina
Format: Article
Language:English
Subjects:
Anthropogenic factors
anthropogenic pressures
Aromatic compounds
Aromatic hydrocarbons
Basins
Biodiversity and Ecology
Chemical contaminants
Chemical contamination
Chemical pollution
Contaminants
Contamination
Continental shelves
Earth Sciences
Economic development
Economics
Environmental monitoring
Environmental regulations
Environmental Sciences
Hydrology
Income
large river basins
long‐term monitoring program
micropollutant yields
Micropollutants
Monitoring
Multiscale analysis
Observatories
Outlets
PCB
persistent organic pollutants
Pollution monitoring
Polychlorinated biphenyls
Polycyclic aromatic hydrocarbons
River basin development
River basins
Rivers
Sciences of the Universe
Sediment
Sediment pollution
Sediments
trace metal elements
Trace metals
Water pollution
Watersheds
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Summary:For more than half a century, chemical contamination has progressively spread to all the large river basins. Large river outlets integrate multiple anthropogenic pressures in watersheds, making them the largest source of sediment‐bound contaminants to continental shelf areas. However, comparing particulate micropollutant contaminations between the large river basins is a challenging task, especially due to the scarcity of long‐term river monitoring programs. Here we address this issue, with a focus on legacy particulate micropollutants (polychlorobiphenyls [PCBi], polycyclic aromatic hydrocarbons [PAHs] and trace metal elements [TME]) yields. For this purpose, we employed a bottom‐up multiscale approach to chemical contamination in river basins that takes micropollutant yields measured in the Rhône River sub‐basins (France) as a benchmark of other large river basins. Data on the Rhône River basin came from a unique 10‐year‐long monitoring program within the Rhône Sediment Observatory (OSR), and were compared to data gathered on 18 major worldwide river outlets. The Rhône River basin is far cleaner now than a few decades ago, likely due to environmental regulations. At a wider spatial scale, our results depict an overall contamination gradient splitting the most heavily contaminated river basins, located in developing and industrializing low‐to‐middle‐income countries, from the least contaminated rivers located in developed high‐income countries. We argue that chemical contamination levels of large river basins depend on their stage of economic development. For more than half a century, chemical contamination has progressively spread to all the large river basins. Comparing particulate micropollutant contaminations between the large river basins is a challenging task, as there is a lack of large‐scale monitoring for estimating chemical contamination at river outlets. Here we address this issue using yields of legacy micropollutants in a bottom‐up multiscale approach, from the well‐monitored Rhône River sub‐basins (as benchmark) up to the major large river basins. Results show an overall chemical contamination gradient that splits the most‐contaminated river basins, located in developing and industrializing low‐to‐middle‐income countries, from the least contaminated rivers located in developed high‐income countries. Data from the pluri‐decadal monitoring program on the Rhône River basin shows that since the 1980s, this river has transitioned from the more‐co
ISSN:0885-6087
1099-1085
DOI:10.1002/hyp.14511