Lake-groundwater interactions and sensitivity to climate and environmental change

Marie Arnoux – 2016

In the face of modern anthropogenic pressures the preservation of freshwater resources, particularly groundwater, is paramount. This study investigates interactions between small lakes and groundwater in Quebec, where more than 10% of the territory is covered by freshwater including one million inventoried lakes, to determine whether these lakes may be used as indicators of groundwater change.

Twenty-one kettle lakes, set in fluvioglacial deposits, have been specifically targeted for this study due to the high likelihood of connection to shallow unconfined aquifers. Groundwater flows were quantified via lake water balances coupled with two natural tracers of groundwater: stable isotopes of water and Radon-222. On a regional scale the majority of these lakes are characterized by an important annual groundwater inflow and a short-to-medium groundwater flushing time. Daily multi-layer modeling of one of the study lakes, Lake Lacasse, highlights the importance of conducting measurements of these complementary tracers on the water column at the local scale.

Different climate and environmental change scenarios were tested to determine the longterm evolution of lake geochemistry. The results indicate that the sensitivity of the isotopic composition of lake water to changes in recharge by year 2050 is mainly controlled by the amount of the total lake balance contributed by groundwater, with an optimum sensitivity for 50-80% of the total inflows contributed by groundwater. This research demonstrates that the geochemical signatures of lakes can be used to indicate future groundwater change in response to climate and environmental evolution, which may assist in improvements to the sustainable management of freshwater resources.