Assessing the impacts of hydrologic and land use alterations on water temperature in the Farmington River basin in Connecticut

Aquatic ecosystems can be significantly altered by the construction of dams and modification of riparian buffers, and the effects are often reflected in spatial and temporal changes to water temperature. To investigate the implications for water temperature of spatially and temporally varying ripari...

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Bibliographic Details
Published in:Hydrology and earth system sciences 2019-11, Vol.23 (11), p.4491-4508
Main Authors: Yearsley, John R, Sun, Ning, Baptiste, Marisa, Nijssen, Bart
Format: Article
Language:English
Subjects:
Aquatic ecosystems
Budgets
Buffers
Computer simulation
Dam construction
Dams
Decision support systems
Deforestation
Ecosystems
Energy budget
Evaluation
Heterogeneity
Hydraulic flow
Hydrologic models
Hydrologic regime
Hydrology
Land use
Land use controls
Modelling
Patchiness
Plant cover
Reservoirs
Reservoirs (Water)
Riparian buffers
Riparian vegetation
River basins
Rivers
Seasonal variation
Seasonal variations
Spatial heterogeneity
Stream discharge
Stream flow
Streamflow
Streams
Temporal variations
Thermal energy
Thermal stratification
Water
Water temperature
Watershed management
Watersheds
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Summary:Aquatic ecosystems can be significantly altered by the construction of dams and modification of riparian buffers, and the effects are often reflected in spatial and temporal changes to water temperature. To investigate the implications for water temperature of spatially and temporally varying riparian buffers and dam-induced hydrologic alterations, we have implemented a modeling system (DHSVM-RBM) within the framework of the state-space paradigm that couples a spatially distributed land surface hydrologic model, DHSVM, with the distributed stream temperature model, RBM. The basic modeling system has been applied previously to several similar-sized watersheds. However, we have made enhancements to DHSVM-RBM that simulate spatial heterogeneity and temporal variation (i.e., seasonal changes in canopy cover) in riparian vegetation, and we included additional features in DHSVM-RBM that provide the capability for simulating the impacts of reservoirs that may develop thermal stratification. We have tested the modeling system in the Farmington River basin in the Connecticut River system, which includes varying types of watershed development (e.g., deforestation and reservoirs) that can alter the streams' hydrologic regime and thermal energy budget. We evaluated streamflow and stream temperature simulations against all available observations distributed along the Farmington River basin. Results based on metrics recommended for model evaluation compare well to those obtained in similar studies. We demonstrate the way in which the model system can provide decision support for watershed planning by simulating a limited number of scenarios associated with hydrologic and land use alterations.
ISSN:1607-7938
1027-5606
1607-7938
DOI:10.5194/hess-23-4491-2019