Land-Cover and Climatic Controls on Water Temperature, Flow Permanence, and Fragmentation of Great Basin Stream Networks

The seasonal and inter-annual variability of flow presence and water temperature within headwater streams of the Great Basin of the western United States limit the occurrence and distribution of coldwater fish and other aquatic species. To evaluate changes in flow presence and water temperature duri...

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Bibliographic Details
Published inWater (Basel) Vol. 12; no. 7; p. 1962
Main Authors Gendaszek, Andrew S., Dunham, Jason B., Torgersen, Christian E., Hockman-Wert, David P., Heck, Michael P., Thorson, Justin, Mintz, Jeffrey, Allai, Todd
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.07.2020
Subjects
Annual variations
Basins (Geology)
Climate
Climatic changes
Climatic data
Data collection
Drought
Environmental aspects
Flow
flow permanence
Fragmentation
Generalized linear models
Geographical distribution
Great Basin
Groundwater
Groundwater discharge
Groundwater runoff
Land cover
Land use
Precipitation
Snowmelt
spatial stream network modeling
Streams
Trout
Vegetation
Water temperature
Watershed management
Watersheds
United States
United States > US
Great Basin
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Summary:The seasonal and inter-annual variability of flow presence and water temperature within headwater streams of the Great Basin of the western United States limit the occurrence and distribution of coldwater fish and other aquatic species. To evaluate changes in flow presence and water temperature during seasonal dry periods, we developed spatial stream network (SSN) models from remotely sensed land-cover and climatic data that account for autocovariance within stream networks to predict the May to August flow presence and water temperature between 2015 and 2017 in two arid watersheds within the Great Basin: Willow and Whitehorse Creeks in southeastern Oregon and Willow and Rock Creeks in northern Nevada. The inclusion of spatial autocovariance structures improved the predictive performance of the May water temperature model when the stream networks were most connected, but only marginally improved the August water temperature model when the stream networks were most fragmented. As stream network fragmentation increased from the spring to the summer, the SSN models revealed a shift in the scale of processes affecting flow presence and water temperature from watershed-scale processes like snowmelt during high-runoff seasons to local processes like groundwater discharge during sustained seasonal dry periods.
ISSN:2073-4441
2073-4441
DOI:10.3390/w12071962