Journal
AQUATIC SCIENCES
Volume 83, Issue 2, Pages -Publisher
SPRINGER BASEL AG
DOI: 10.1007/s00027-021-00795-7
Keywords
Nitrogen removal rate; Nitrogen removal efficiency; Combined nitrification– denitrification; Sediment porewater fluxes; Whole-lake nitrogen budget
Funding
- Lib4RI - Library for the Research Institutes within the ETH Domain: Eawag
- Lib4RI - Library for the Research Institutes within the ETH Domain: Empa
- Lib4RI - Library for the Research Institutes within the ETH Domain: PSI
- Lib4RI - Library for the Research Institutes within the ETH Domain: WSL
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Freshwater lakes play a crucial role in removing excessive anthropogenic nitrogen loads before they reach coastal oceans. The study found that eutrophic lakes are more effective at removing nitrogen compared to oligotrophic lakes, with factors such as historic nitrogen loads, nitrate concentration, and seasonal oxygen fluxes influencing the removal rates. Increasing oxygen levels stimulate sediment mineralization and nitrification, ultimately enhancing denitrification activity in eutrophic lakes.
Freshwater lakes are essential hotspots for the removal of excessive anthropogenic nitrogen (N) loads transported from the land to coastal oceans. The biogeochemical processes responsible for N removal, the corresponding transformation rates and overall removal efficiencies differ between lakes, however, it is unclear what the main controlling factors are. Here, we investigated the factors that moderate the rates of N removal under contrasting trophic states in two lakes located in central Switzerland. In the eutrophic Lake Baldegg and the oligotrophic Lake Sarnen, we specifically examined seasonal sediment porewater chemistry, organic matter sedimentation rates, as well as 33-year of historic water column data. We find that the eutrophic Lake Baldegg, which contributed to the removal of 20 +/- 6.6 gN m(-2) year(-1), effectively removed two-thirds of the total areal N load. In stark contrast, the more oligotrophic Lake Sarnen contributed to 3.2 +/- 4.2 gN m(-2) year(-1), and had removed only one-third of the areal N load. The historic dataset of the eutrophic lake revealed a close linkage between annual loads of dissolved N (DN) and removal rates (NRR = 0.63 x DN load) and a significant correlation of the concentration of bottom water nitrate and removal rates. We further show that the seasonal increase in N removal rates of the eutrophic lake correlated significantly with seasonal oxygen fluxes measured across the water-sediment interface (R-2 = 0.75). We suggest that increasing oxygen enhances sediment mineralization and stimulates nitrification, indirectly enhancing denitrification activity.
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