Water Temperature in Rivers and Streams
Increases in summer stream temperature as a result of human impacts and climate change may exceed the thermal tolerances of aquatic biota that are adapted to colder environments and climates. The combined effects of humans and climate change are of global concern across the range of coldwater aquatic organisms.
We use state-of-the-art technology and techniques to quantify spatial and temporal variability in stream temperature using field surveys, remote sensing, and spatially explicit modeling. This information is used to understand and predict the effects of climate change, riparian management, and restoration on cold-water habitats and the thermal diversity of rivers and streams.
Featured Studies
- Longitudinal Patterns of Fish Assemblage Structure, Stream Habitat, and Water Temperature in the Lower Crooked River, Oregon
- Primer for Identifying Cold-water Thermal Refugia for the Protection and Restoration of Habitat for Native Salmonids
- Integrating Future Climate Change and Riparian Land-Use to Forecast the Effects of Stream Warming on Species Invasions and Their Impacts on Native Salmonids
- Using Remote Sensing, Modeling, and In Situ Thermal Mapping to Evaluate Potential Effects of Thinning in Riparian Forests on Stream Temperature
Below are other science projects associated with this project.
Below are data or web applications associated with this project.
Below are publications associated with this project.
Temperature-associated population diversity in salmon confers benefits to mobile consumers
Longitudinal patterns of fish assemblages, aquatic habitat, and water temperature in the Lower Crooked River, Oregon
Comment: "Perspectives on water flow and the interpretations of FLIR images" J.Range Manage. 55: 106-111 2002
Multiscale thermal refugia and stream habitat associations of chinook salmon in northwestern Oregon
Increases in summer stream temperature as a result of human impacts and climate change may exceed the thermal tolerances of aquatic biota that are adapted to colder environments and climates. The combined effects of humans and climate change are of global concern across the range of coldwater aquatic organisms.
We use state-of-the-art technology and techniques to quantify spatial and temporal variability in stream temperature using field surveys, remote sensing, and spatially explicit modeling. This information is used to understand and predict the effects of climate change, riparian management, and restoration on cold-water habitats and the thermal diversity of rivers and streams.
Featured Studies
- Longitudinal Patterns of Fish Assemblage Structure, Stream Habitat, and Water Temperature in the Lower Crooked River, Oregon
- Primer for Identifying Cold-water Thermal Refugia for the Protection and Restoration of Habitat for Native Salmonids
- Integrating Future Climate Change and Riparian Land-Use to Forecast the Effects of Stream Warming on Species Invasions and Their Impacts on Native Salmonids
- Using Remote Sensing, Modeling, and In Situ Thermal Mapping to Evaluate Potential Effects of Thinning in Riparian Forests on Stream Temperature
Below are other science projects associated with this project.
Below are data or web applications associated with this project.
Below are publications associated with this project.