Catchment soil characteristics predict organic carbon, nitrogen, and phosphorus levels in temperate lakes

Allochthonous supply of dissolved organic matter (DOM) and nutrients from the catchment have a substantial impact on the physical and chemical properties of lake water. Transport of DOM and nutrients is affected by different catchment characteristics, e.g., catchment area, soil and land cover, and population density. The aim of this study was to relate geological, hydrological, land-cover, and soil characteristics of 52 temperate catchments in Estonia to variability in DOM (measured as dissolved organic carbon [DOC]), total organic nitrogen (TON), and total phosphorus (TP) in lakes and to assess the relative importance of different land-cover and soil types as sources of these substances. DOC, TON, and TP were very diverse in the studied lakes. Strong positive correlation between DOC and TON indicated that these substances had similar concentration patterns and sources. Catchment soil cover was the best predictor of DOC, TON, and TP levels in lakes, explaining up to 43.8% of their variabilities. This observation can partly be explained by different soil organic carbon (SOC) content: soils with higher SOC were associated with higher lake DOC and TON, whereas soils with low SOC corresponded to lower DOC and TON. Similar to other temperate lakes, bogs and peat soils were a major source of DOM in our studied lakes. DOC, TON, and color were positively associated with percentages of peat soils in the catchment. On the other hand, TP increased with the proportion of urban areas in the catchments, indicating the importance of human impact on its concentration. Understanding the impact of different catchment characteristics on DOC, TON, and TP in temperate lakes is crucial for developing transport models used for predicting future levels of DOM and nutrients under changing climate and land use.

Automated summary

The geological, hydrological, land-cover, and soil characteristics of catchments have a significant impact on the levels of dissolved organic matter (DOM), total organic nitrogen (TON), and total phosphorus (TP) in lakes. Soil cover in catchments is the best predictor of DOM, TON, and TP levels in lakes, with different soil organic carbon content playing a role in their variability. Bogs and peat soils are major sources of DOM in temperate lakes, while urban areas contribute to higher TP concentrations. Understanding the influence of catchment characteristics on DOM, TON, and TP is crucial for predicting future levels under changing climate and land use.