Seven lakes were surveyed in Switzerland three times over summer: Soppen, Hallwil and Baldegg in the lowlands and Lioson, Chavonnes, Bretaye and Noir in the Alps. Complete budgets for CH4 and CO2 were measured, including sediment production, water column accumulation, and atmospheric flux. Fluxes for N2O were also measured. Various physical, chemical and biological variables were also measured, including light extinction, stability, nutrient and carbon concentrations, and chlorophyll and algal concentrations.
The findings of this project encompass two themes: (1) the balance of GHG emissions according to trophic state; and (2) trophic state interactions with potential drivers of aquatic CH4 dynamics. To the first, we found that indeed the balance of GHG emissions shift with trophic state, such that more eutrophic (i.e. productive) systems emit more GHGs, particularly CH4. The meso-oligotrophic (i.e. less productive) systems, however, tend to emit more N2O than the eutrophic ones. We found that Alpine lakes, which were thought to be pristine systems, can also be eutrophic and significant carbon emitters. If these mountainous regions are to experience climate change going forward, then they may become eutrophic and negatively feedback on the climate as they also become significant carbon emitters.
Secondly, this project has provided a more in-depth understanding of the trophic state interactions of potential drivers of aquatic CH4 dynamics in lakes. Our work has shown that eutrophic systems are higher in overall CH4 concentrations and significant CH4 emitters. Instead of finding a relationship between CH4 and chlorophyll and/or P as we expected, we found a negative correlation between N and CH4 variables. The relationship between N and CH4 is rather understudied but may be important in aquatic systems. We also found positive correlations between CH4 and some physical variables such that lakes with stronger stratification and less light penetration had higher concentrations of CH4 throughout. But the relationships with nutrients was stronger than physical variables, so the CH4 dynamics in these lakes are indeed driven more by trophic state.