Variable wildfire impacts on the seasonal water temperatures of western US streams: A retrospective study

Recent increases in the burn area and severity of wildfires in the western US have raised concerns about the impact on stream water temperature–a key determinant of cold-water fish habitats. However, the effect on seasonal water temperatures of concern, including winter and summer, are not fully und...

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Bibliographic Details
Published in:PloS one 2022-07, Vol.17 (7), p.e0268452-e0268452
Main Authors: Beyene, Mussie T, Leibowitz, Scott G, Snyder, Marcia, Ebersole, Joseph L, Almquist, Vance W
Format: Article
Language:English
Subjects:
Analytical methods
Biology and Life Sciences
Burns
Climate change
Cold water
Creeks
Creeks & streams
Downstream
Earth Sciences
Ecology and Environmental Sciences
Environmental aspects
ENVIRONMENTAL SCIENCES
Evaluation
Fire effects
Forest & brush fires
Gibbons
Heat
Hydrology
Influence
Median (statistics)
Meteorology
Precipitation
Radiation
Seasons
Standard error
Stream flow
Stream water
Streams
Summer
Surface water
Temperature data
Temperature effects
Water temperature
Watersheds
Wildfires
Winter
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Summary:Recent increases in the burn area and severity of wildfires in the western US have raised concerns about the impact on stream water temperature–a key determinant of cold-water fish habitats. However, the effect on seasonal water temperatures of concern, including winter and summer, are not fully understood. In this study, we assessed the impact of wildfire burns at Boulder Creek (Oregon), Elk Creek (Oregon), and Gibbon River (Wyoming) watersheds on the downstream winter and summer water temperatures for the first three post-fire years. To obtain results independent of the choice of the analytical method, we evaluated the consequence of each burn using three different statistical approaches that utilize local water temperature data. Our results from the three approaches indicated that the response of water temperatures to wildfire burns varied across seasons and sites. Wildfire burns were associated with a median increase of up to 0.56°C (Standard Error; S.E. < 0.23°C) in the summer mean water temperatures (MWT) and 62 degree-day Celsius (DDC; S.E. < 20.7 DDC) in the summer accumulated degree days (ADD) for the three subsequent years across studied stream sites. Interestingly, these burns also corresponded to a median decrease of up to 0.49°C (S.E. < 0.45°C) in the winter MWT and 39 DDC (S.E. < 40.5 DDC) in the winter ADD for the same period across sites. Wildfire effects on the downstream water temperatures diminished with increasing site distance from the burn perimeter. Our analyses demonstrated that analytical methods that utilize local watershed data could be applied to evaluate fire effects on downstream water temperatures.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0268452