Eutrophication evolution trajectory influenced by human activities and climate in the shallow Lake Gehu, China

Lake eutrophication has become a global environmental pollution problem. Analysis of the eutrophication recovery trajectory of lakes can help to accurately implement regulations and reduce the cost of management. The degradation and recovery trajectories of Lake Gehu were firstly analyzed based on 34-years monitoring data of water quality. A dynamic correlation analysis of the relationship between chlorophyll-a (Chla) and the total phosphorus (TP) (total nitrogen [TN]) at an annual scale was conducted using the filtering trajectory method (FTM). The result showed that the recovery trajectory of Lake Gehu was nonlinear, and showed a short lag time in Chla decrease. The regime shift from a clear-water state to a turbid-water state occurred in Lake Gehu when the TP threshold was 120 mu g/L. Combined the filtering trajectory diagram with a principal component analysis, the results revealed that the adverse climate change did not completely offset the positive effect of nutrient load reduction, which required further attention and had significance for eutrophication control. According to the dynamic changes in the algae production efficiency of total phosphorus (ETP), the result showed that the sensitivity of lake eutrophication increased and the TP carrying concentration reduced by 40%-60%. The water quality goal for controlling algae was determined as TP = 40 mu g/L (Chla = 10 mu g/L), which was 20% stricter than the national standard (TP = 50 mu g/L). In conclusion, aquatic vegetation restoration and biological manipulation can be effective alternatives for controlling eutrophication in addition to nutrient load reduction. The eutrophication control target and adaptive strategies were determined according to the recovery trajectory of Lake Gehu in this study. The ETP has reference significance for the management of shallow lakes.

Automated summary

Lake eutrophication is a global environmental pollution problem. This study analyzed the degradation and recovery trajectories of Lake Gehu based on 34-year water quality monitoring data. The results showed a nonlinear recovery trajectory with a short lag time in chlorophyll-a decrease. The adverse climate change did not completely offset the positive effect of nutrient load reduction, emphasizing the importance of further attention to eutrophication control. The sensitivity of lake eutrophication increased and the total phosphorus carrying concentration reduced by 40%-60% according to the changes in algae production efficiency of total phosphorus. The water quality goal for controlling algae was determined as TP = 40μg/L (Chla = 10μg/L), which was 20% stricter than the national standard. Aquatic vegetation restoration and biological manipulation were identified as effective alternatives for controlling eutrophication.