Tin contamination in sediments of Lake Zurich: source, spread, history and risk assessment

Industrial activities of a silk dyeing factory in Thalwil, on the shore of Lake Zurich, Switzerland, caused extreme Sn contamination of lake sediments. In this study, we determine the contamination source, spread, and age using a multiproxy approach. We used X-ray fluorescence spectroscopy (XRF) cor...

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Bibliographic Details
Published in:Swiss Journal of geosciences 2024-12, Vol.117 (1), p.22-15, Article 22
Main Authors: Roethlin, Remo L, Meister, Aurélia C E, Gilli, Adrian, Lennartz, Sinikka T, Amsler, Helen Eri, Dittrich, Maria, Wehrli, Bernhard, Schönbächler, Maria, Dubois, Nathalie
Format: Article
Language:English
Subjects:
19th century
Biota
Chloride
Contaminated sediments
Contamination
Drinking water
Fluorescence
Fluorescence spectroscopy
Heavy metals
Industrial areas
Industrial Revolution
Lake deposits
Lake sediments
Lake Zurich
Lakes
Plant layout
Pore water
Risk assessment
Scanning electron microscopy
Sediment
Sediment pollution
Sediments
Silk
Silk industry
Spectroscopy
Sulfides
Sulphides
Tin
Tin compounds
Toxicity
Turbidites
X ray fluorescence analysis
X-ray fluorescence
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Summary:Industrial activities of a silk dyeing factory in Thalwil, on the shore of Lake Zurich, Switzerland, caused extreme Sn contamination of lake sediments. In this study, we determine the contamination source, spread, and age using a multiproxy approach. We used X-ray fluorescence spectroscopy (XRF) core scanning and further geochemical analyses to assess the contamination spreading and thickness in the sedimentary column. We found elevated Sn levels throughout sediments of Lake Zurich, ranging from 177  in front of the former silk factory to 0.05  at the southeast end (background: ca. 0.006  ). The rapid concentration drop away from the shore suggests quick precipitation of a sparingly soluble inorganic Sn compound, which is confirmed by Scanning Electron Microscope Imaging in tandem with Energy-dispersive XRF spectroscopy (SEM-EDX) data. The Sn XRF profile of a varved core indicates a contamination onset in the early 1890s, a maximum around 1900, and a gradual decrease to low levels in the 1940s. High Sn concentrations in turbidite layers from the deep basin indicate that mass movements physically remobilised Sn. However, in stable conditions, in-situ porewater measurements (conc. < 0.5  ) using dialyse plates show little Sn remobilisation into the lake water (0.05  ). The low remobilisation, reducing conditions, and high sulphide contents in the contaminated layers suggest that Sn is firmly bound to the sediments. Combined with the low toxicity of Sn, we conclude that the Sn contamination poses no threat to lake biota or drinking water production. The online version contains supplementary material available at 10.1186/s00015-024-00471-6.
ISSN:1661-8726
1661-8734
1661-8734
DOI:10.1186/s00015-024-00471-6