T-133-20
Wildfire Effects on Stream Metabolism Across Gradients of Fire Severity and Watershed Geomorphology at Multiple Spatial Scales

Emily Davis , School of Aquatic and Fishery Sciences, University of Washington, Seattle, WA
Daniel Schindler , School of Aquatic and Fishery Sciences, University of Washington, Seattle, WA
Colden V. Baxter , Stream Ecology Center, Idaho State University, Pocatello, ID
Christian Torgersen , Forest and Rangeland Ecosystem Science Center, US Geological Survey, Seattle, WA
KathiJo Jankowski , School of Aquatic and Fishery Sciences, University of Washington, Seattle, WA
As climate change shifts and intensifies fire regimes, it is important to understand stream ecosystem responses to fire. How stream metabolism responds remains largely unexplored. We investigated effects of fire severity and watershed geomorphology on stream ecosystem metabolism at multiple spatial scales in an Idaho wilderness watershed. We measured dissolved oxygen, temperature, and irradiance in 18 streams varying in fire history and watershed characteristics in order to model diel oxygen dynamics. Using this model, we estimated rates of production (P) and respiration (R), then used P:R as an index of metabolic state in streams. We found that post-fire riparian canopy recovery strongly influenced stream metabolic state. Severely burned streams with dense riparian regrowth were net heterotrophic, whereas streams with less canopy recovery were net autotrophic. Fire effects on stream metabolic state were highly mediated by watershed geomorphology, with the strongest long-term changes observed in low-order, narrow, steep streams. Effect sizes of fire and watershed geomorphology on stream metabolism changed from fine spatial scale (500-m riparian buffer) to coarse (basin), and were strongest at fine scales. These results indicate that the physical habitat template mediates aquatic ecosystem response to disturbance, and that context and scale should be explicitly considered in assessments.