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Tziritis, D. E., Fidelibus, M. D., Guler, C., Külls, C., & Sachsamanoglou, K. (2022). An integrated hydrogeochemical approach to identify multiple salinization sources of a coastal aquifer (Rhodope, Northern Greece). In 2022 Goldschmidt Conference.
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Külls, C., & Bassukas, D. (2022). Groundwater salinization dynamics-an isotope approach. In EGU General Assembly Conference Abstracts (22).
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Külls, C. (2024). Grundwasserqualität im Abstrom der Deponie Ihlenberg.
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Ola, I., Drebenstedt, C., Burgess, R. M., Allan, I. J., Hoth, N., & Külls, C. (2024). Application of Low Density Polyethylene (LDPE) Passive Samplers for Monitoring PAHs in Groundwater.
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Edmunds, W. M. (1996). Bromine geochemistry of british groundwaters. Mineralogical Magazine, 60(399), 275–284.
Abstract: \textlessp\textgreater The concentrations of Br in potable groundwaters in the United Kingdom range from 60 to 340 µg 1 \textlesssup\textgreater-1\textless/sup\textgreater . The occurrence of Br is described in terms of the Br/Cl weight ratio which enables small changes in bromide concentrations to be assessed in terms of salinity. Median values of Br/Cl in groundwaters range from 2.60 to 5.15 × 10 \textlesssup\textgreater−3\textless/sup\textgreater compared with a sea water ratio of 3.47× 10 \textlesssup\textgreater−3\textless/sup\textgreater . In recent shallow groundwaters the Br/Cl ratio is rather variable in response to a range of natural and anthropogenic inputs (marine and industrial aerosols, industrial and agricultural chemicals including road salt). Some slight enrichment in Br/Cl also occurs naturally during infiltration as a result of biogeochemical processes. \textless/p\textgreater
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