Tritium across the hydrologic systems of southern Ontario, Canada: implications for groundwater age dating in the Great Lakes Basin

• Published in: Hydrogeology journal Vol. 31; no. 3; pp. 641 - 659
• Main Authors: Priebe, E. H., Hamilton, S. M., Lemieux, A., Rowan, D. J., Clark, I. D.
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.05.2023; Springer Nature B.V
• Subjects: Anthropogenic factors; Aquatic Pollution; Aquifers; Bedrock; Earth and Environmental Science; Earth Sciences; Geology; Geophysics/Geodesy; Groundwater; Groundwater age; Groundwater data; Human influences; Hydrogeology; Hydrologic systems; Hydrology; Hydrology/Water Resources; Indication; Interpolation; Lakes; Precipitation; Precipitation monitoring; Recharge; Resolvers; Temporal variability; Temporal variations; Tritium; Waste Water Technology; Water Management; Water Pollution Control; Water Quality/Water Pollution; Canada; Ontario Canada; Canada; Environmental tracers; Isotopes; Radioactive isotopes; Groundwater age
• ISSN: 1431-2174; 1435-0157
• DOI: 10.1007/s10040-023-02626-5

Modern, ambient tritium concentrations in precipitation are lower and more temporally consistent now that they have recovered from the historic thermonuclear bomb peak of the mid-1960s. With the bomb peak no longer the overriding influence on atmospheric tritium concentrations, anthropogenic point sources, such as nuclear-generating stations (NGS), have the largest influence, though the extent and temporal variability of this influence remains uncharacterized. The lack of precipitation monitoring locations means that spatial trends in tritium concentrations in precipitation are unknown. To address this data gap, tritium concentrations in shallow modern groundwater are interpolated throughout southern Ontario (Canada), at the center of the Great Lakes Basin, and the interpolation is tested as a precipitation proxy with a statistical comparison that shows good agreement between the shallow groundwater and precipitation datasets. The shallow groundwater tritium interpolation is used to delineate the extent of NGS influence as representing 66% of the study area. Recharge timings in the subcropping bedrock aquifers of the study area are interpreted qualitatively in areas outside of NGS influence to be primarily a mix of pre-bomb and modern recharge, with no indication of peak recharge levels remaining. The influence of drift thickness on the proportion of tritium-dead versus tritium-live samples is observed spatially and confirmed by comparing data distributions. The oldest waters (pre-1953) tend to occur in subcropping bedrock aquifers underlying the thickest sediment packages.