Areas of Work
Disposal sites and isotope methods

Most chemical elements have isotopes. For example, hydrogen has two stable isotopes, ¹H (99,99 %) and ²H (Deuterium, 0,01 %), and one radioactive isotope ³H (Tritium). Analyzing stable isotopes, no absolute values, but isotope ratios are determined. These ratios are specified in reference to an international standard. By physical, chemical and biological processes the isotope ratios can be changed. These isotope effects lead to a spatial and temporal marking of different element cycles. In case of the radioactive isotope tritium, the radioactive decay is measured and specified by tritium units (TU).

The content of a municipal waste landfill effects the environment mainly by the discharge of gas and leachate. In most instances, the isotope signatures of CH₄ and CO₂ in the leachates of municipal waste landfills differ significantly from natural isotope ratios. Experience has shown that isotope methods are a very useful tool for the determination of the processes occouring in disposal sites).Thus, dispersing leachates and their contact to groundwater can be identified).

Plotting ð²H against ð¹⁸O in a diagram, the values of meteoric water are on the so-called meteoric water line. If the precipitation water experiences evaporation, which is characteristic for stagnant water bodies under warm climate conditions, or by irrigation of effluents, ¹⁸O and ²H in water becomes enriched and, therefore, shift rightward of the meteoric water line. In disposal sites with organic burials (e.g. municipal waste landfills) water is formed by the decomposition of the organic material. In this process, hydrogen (H₂) and methane (CH₄) are formed, which causes isotope fractionation between H₂/CH₄ and water. The heavy hydrogen ²H is favored to be incorporated into the water molecule. Therefore, water formed in a disposal site is enriched in ²H in comparison to meteoric water. The enrichment in ²H and a potential enrichment in ¹⁸O due toirrigation or evaporation leads to a characteristic isotope signature. This is shown in the figure by an upward and rightward shift from the meteoric water line. Therefore, a determination of ¹⁸O and ²H signatures can be used to identify biological processes occurring in a disposal site and the percentages of the formed water. By comparing the isotope signature of the water formed in a disposal site with the isotope signature of groundwater, potential mixing processes can be detected.

For decades, the aerial nuclear bomb tests between 1950 and 1963 were the main source of the anthropogenic tritium abundant in the environment. Since the termination of these tests, the tritium content continuously decreases because of radioactive decay of tritium. Experience has shown that leachates from disposal sites have a tritium content of 10 to 200 000 TU. The mean value of 800 TU for leachates clearly exceeds the tritium values of mean precipitation in Europe (approx. 8 TU), shallow groundwater and deep groundwater.´The origin of the high tritium content of leachates can not be explained clearly for the most disposal sites. Potential sources are waste from industry which has produced watches or fluorescence substances. Other sources might by waste from hospitals. However, if a disposal site is marked with ³H, it is an ideal tracer for the dispersion of leachates, because tritium is not influenced by chemical and microbial processes.

Dissolved inorganic carbon (DIC) in water is mostly available as CO₂ and hydrocarbonate (HCO₃^-). Hydrocarbonate is formed predominantly by the dissolution of carbonates due to the reaction with CO₂. If CO₂ is formed organically under anaerobic conditions, the ð¹³C-value is in the range of the organic material. However, if CO₂ is formed under anaerobic conditions concurrently with methane (CH₄), CO₂ is enriched in ¹³C. The formation of hydrocarbonates leads to a further enrichment of ¹³C in hydrocarbonate compared to CO₂. The HCO₃^- and therefore the DIC of leachates from disposal sites are therefore highly enriched in ¹³C. Additionally, leachates have very high concentrations of DIC compared to most of the groundwater. This method allows a detection of small percentages (in %-range) of leachates in groundwater.