Climate Change Demands Adaptive Management of Urban Lakes: Model-Based Assessment of Management Scenarios for Lake Tegel (Berlin, Germany)

Lakes are known to be strongly affected by climate change as a result of their sensitivity to atmospheric forcing. The combined response of urban lakes to climatic changes and to urbanization of the catchment may be further altered by water quality management measures. We studied Lake Tegel in Berli...

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Bibliographic Details
Published in:Water (Basel) 2018-02, Vol.10 (2), p.186
Main Authors: Ladwig, Robert, Furusato, Eiichi, Kirillin, Georgiy, Hinkelmann, Reinhard, Hupfer, Michael
Format: Article
Language:English
Subjects:
Adaptive management
Analysis
Aquatic ecosystems
Atmospheric forcing
Catchments
Climate change
Climate effects
Computer simulation
Dissolved oxygen
Ecosystems
Environmental changes
Global temperature changes
Lakes
Management
Nutrients
Phosphates
Phosphorus
Quality control
Quality management
Rivers
Stratification
Urbanization
Wastewater disposal
Water
Water inflow
Water management
Water quality
Water quality management
Water temperature
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Summary:Lakes are known to be strongly affected by climate change as a result of their sensitivity to atmospheric forcing. The combined response of urban lakes to climatic changes and to urbanization of the catchment may be further altered by water quality management measures. We studied Lake Tegel in Berlin, Germany as a representative urban lake profoundly influenced by intense water management measures and a resulting complex hydrodynamic situation: Lake Tegel is fed by nutrient-rich river discharges and effluents from a phosphorus elimination plant (PEP). We estimated changes in water temperatures, the Wedderburn number, and the buoyancy frequency, as well as concentrations of dissolved oxygen and phosphate under climate change using a one-dimensional vertical hydrodynamic model coupled to a water quality model. Further, we investigated how four management scenarios with varying discharges of the PEP could affect the lake system. In all simulations, water temperatures increased and summer stratification extended. The modeling results demonstrated that the water management system buffers the high nutrient supply from the river inflow and can effectively mitigate negative effects of climate change on Lake Tegel, thus highlighting its importance for the lake ecosystem.
ISSN:2073-4441
2073-4441
DOI:10.3390/w10020186