Integrating Future Climate Change and Riparian Land-Use to Forecast the Effects of Stream Warming on Species Invasions and Their Impacts on Native SalmonidsEPA Grant Number: R833834
Title: Integrating Future Climate Change and Riparian Land-Use to Forecast the Effects of Stream Warming on Species Invasions and Their Impacts on Native Salmonids
Investigators: Olden, Julian D. , Beechie, Timothy , Lawler, Joshua J. , Torgersen, Christian E.
Current Investigators: Olden, Julian D. , Lawler, Joshua J. , Torgersen, Christian E.
Institution: University of Washington , Northwest Fisheries Science Center , USGS Forest and Rangeland Ecosystem Science Center
Current Institution: University of Washington , Northwest Fisheries Science Center
EPA Project Officer: Hiscock, Michael
Project Period: July 1, 2008 through June 30, 2012 (Extended to June 30, 2013)
Project Amount: $587,209
RFA: Ecological Impacts from the Interactions of Climate Change, Land Use Change and Invasive Species: A Joint Research Solicitation - EPA, USDA (2007) RFA Text | Recipients Lists
Research Category: Global Climate Change , Aquatic Ecosystems , Ecosystems , Climate Change
This project develops and applies an analytical framework that quantifies how future climate change and riparian land use influences the direct and indirect effects of invasive species on the survival of Pacific salmon in the John Day River, Oregon. Climate change, increasing agricultural land use, and invasive species threaten the functioning of freshwater ecosystems in the Pacific Northwest. Elevated stream temperature is one of the most pervasive water quality issues in this region, and projected climate change and riparian vegetation loss are predicted to exacerbate this problem. Rising temperatures have direct implications for coldwater native salmon, but they will also alter the composition of aquatic biota by facilitating the range expansion and altering the impacts of warmwater invasive species.
We will integrate climate-change projections, geomorphic sensitivity, riparian land use, stream thermodynamics, and ecological niche modeling to quantify the potential range expansion and temperature-mediated impacts of invasive smallmouth bass (Micropterus dolomieu) and northern pikeminnow (Ptychocheilus oregonensis) in critical habitats that support endangered Chinook salmon (Oncorhynchus tshawytscha). The proposed work will: (1) predict spatiotemporal patterns of riverine thermal regimes in response to future climate change, geomorphic sensitivity, and riparian land-use; (2) forecast species-specific responses to projected future thermal regimes; and (3) evaluate alternative scenarios of climate change to identify critical opportunities for riparian habitat restoration and protection to mediate future climate-induced warming of streams and species invasions.
This project provides both the science and decision-support tools required to forecast with certainty how the interactive effects of climate change, land use change, and invasive species will affect native salmon in the future. Model results provide spatially-explicit predictions of the vulnerability of adult and juvenile Chinook salmon to the direct effects of stream warming associated with climate and land use change, and the indirect, temperature-mediated effects of smallmouth bass and northern pikeminnow range expansion. Model outputs improve the scientific capabilities for guiding management strategies and policies aimed at minimizing the future range expansion of invasive species through protection and restoration of riparian vegetation that creates and maintains coolwater habitat. More broadly, this project and the analytical framework it developed is readily applicable to other species of concern and relevant in other river systems of the Pacific Northwest where the range expansion of warmwater fishes in response to climate change and riparian-habitat loss is ongoing and of imminent threat to native fishes.
Publications and Presentations:Publications have been submitted on this project: View all 26 publications for this project
Journal Articles:Journal Articles have been submitted on this project: View all 16 journal articles for this project
Supplemental Keywords:EPA Region 10, northwest, Washington, WA, spatial scaling, hierarchy, sensitive populations, integrated assessment, general circulation models, landsat, remote sensing, water quality, thermal pollution, zoology,, RFA, Scientific Discipline, Air, Ecosystem Protection/Environmental Exposure & Risk, Aquatic Ecosystems & Estuarine Research, climate change, Air Pollution Effects, Aquatic Ecosystem, Monitoring/Modeling, Environmental Monitoring, Ecological Risk Assessment, Atmosphere, anthropogenic stress, environmental measurement, meteorology, climatic influence, socioeconomics, ecosystem indicators, climate models, aquatic ecosystems, environmental stress, invasive species, coastal ecosystems, global climate models, land and water resources, climate model, ecosystem stress, ecological models, air quality, atmospheric chemistry, climate variability, Global Climate Change
Progress and Final Reports:2009 Progress Report
2010 Progress Report
2011 Progress Report
2012 Progress Report