Combining XAS speciation and Zn isotopes to track past eutrophication in lake sediments : The example of Baldeggersee (Switzerland)

Among transition elements, Zn has attracted a great deal of interest because it is an essential nutrient at low concentrations, but it can also be toxic when present at high concentrations in ecosystems (Morel et al., 2003). In the present study, the isotopic signature and crystal-chemical of Zn were followed along a sediment core from a prealpine lake that experienced a marked eutrophication in order to explore the potential of this approach at tracking past environmental conditions of continental lake-catchment systems. Lake Baldeggersee (Luzern, Switzerland) is located at an elevation of 900 m in the Swiss Prealps. It experienced a period of strong eutrophication due to intensive farming in its catchment (Lotter et al., 1997). These led to the formation of varved sediments over one century prior to artificial lake aeration (Wehrli et al., 1997). This enabled us to correlate Zn speciation and isotopic signatures to the history of the water column. Results indicate that both Zn speciation and isotopes are distinct between sediments deposited during mesotrophic and eutrophic conditions in the water column: During the mesotrophic period, sedimentation was mainly detrital and Zn is mainly found associated with clay minerals in the sediments. During the eutrophic period, sedimentation was dominated by biological activity in the lake and Zn mainly occurs as ZnS in the sediments. Zn isotopes recorded these changes in the sedimentation regime, with δ66ZnJMC values around +0.2 % for the sediments of the mesotrophic period and δ66ZnJMC values around 0 % for the sediments of the eutrophic period. Comparison with the results from a study on the seasonal variation of the isotope signature of Zn in settling sediment of another prealpine lake (Peel et al., 2010) suggests that the enrichment in light Zn isotopes in the eutrophic sediments is in line with predominant Zn input with settling biomass (algae). Since lake eutrophication is mainly related to hydrological conditions and occupancy of the related catchment, these results emphasize the great potential of such a combination of molecular level speciation and Zn isotopes in lake sediments cores to track paleo-climatic or paleo-environmental conditions in lake catchments. Lotter A.F., Sturm M., Teranes J.L. and Wehrli B. (1997) Varve fromation since 1885 and high-resolution varve analyses in hypertrophic Baldeggersee (Switzerland) Aquatic Sciences 59, 304-325. Morel F. M. M. and Price N. M. (2003) The biogeochemical cycles of trace metals in the oceans. Science 300, 944-947. Peel K., Weiss D., Sigg L. (2010) Zinc isotope composition of settling particles as a proxy for biogeochemical processes in lakes: Insights from the eutrophic Lake Greifen, Switzerland. Limnol. Oceanogr., 54(5), 1699-1708. Wehrli, B.; Lotter, A.F.; Schaller, T.; Sturm, M. (1997) High-resolution varve studies in Baldeggersee (Switzerland): Project overview and limnological background data. Aquatic Sciences 59, 285-294).