2009
DOI: 10.1029/2008gl034588
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Effects of fire‐precipitation timing and regime on post‐fire sediment delivery in Pacific Northwest forests

Abstract: [1] Wildfires affect the coupled dynamics of vegetation, runoff response, and sediment production, as well as the sequencing of post-fire precipitation and snowmelt in forested watersheds. We examined these interactions by applying a spatially distributed hydrologic model to multiple-year periods before and after a major fire that occurred in 1970 in the Entiat River basin, Washington. The effects of precipitation sequencing on post-fire sediment delivery were examined by simulating the 1970 fire as if it had … Show more

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Cited by 20 publications
(10 citation statements)
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“…DHSVM (Wigmosta et al ., ) is a physically based, fully distributed time‐continuous hydrologic model that mostly has been applied to mountainous watersheds at a high spatial resolution (30 m to hundreds of metres) to simulate surface and subsurface run‐off at subdaily to hourly time steps. It has been extensively applied in numerous studies on different aspects of hydrology, for example, mountain hydrology (Leung and Wigmosta, ; Bowling and Lettenmaier, ; Whitaker et al ., ), urban hydrology under conditions of climate and land cover change (Cuo et al ., , ) and sediment transport (Doten et al ., ; Lanini et al ., ). DSHVM operates on spatially linked grid cells, each of which employs full water and energy balance solutions.…”
Section: Methodsmentioning
confidence: 97%
“…DHSVM (Wigmosta et al ., ) is a physically based, fully distributed time‐continuous hydrologic model that mostly has been applied to mountainous watersheds at a high spatial resolution (30 m to hundreds of metres) to simulate surface and subsurface run‐off at subdaily to hourly time steps. It has been extensively applied in numerous studies on different aspects of hydrology, for example, mountain hydrology (Leung and Wigmosta, ; Bowling and Lettenmaier, ; Whitaker et al ., ), urban hydrology under conditions of climate and land cover change (Cuo et al ., , ) and sediment transport (Doten et al ., ; Lanini et al ., ). DSHVM operates on spatially linked grid cells, each of which employs full water and energy balance solutions.…”
Section: Methodsmentioning
confidence: 97%
“…The explicit representations of evapotranspiration and soil water dynamics make the model a suitable tool for runoff prediction resulting from land-cover changes (Vanshaar et al, 2002). DHSVM has been applied to a variety of forested settings in Pacific Northwest where it was demonstrated to accurately simulate streamflows over multi-decadal time periods that capture forest regeneration and regrowth after harvesting (Waichler et al, 2005), post-fire hydrological processes (Lanini et al, 2009), and predict how flows may be affected by forest roads (LaMarche and Lettenmaier, 2001).…”
Section: Model Descriptionsmentioning
confidence: 99%
“…Although forest fire disturbance is extensive in the snow-dominated headwaters of most western USA watersheds (Gleason et al, 2013) and such disturbance is projected to increase across the western USA (Moritz et al, 2012;Abatzoglou and Kolden, 2013;Dennison et al, 2014), forest fire impacts on snow accumulation and snowmelt patterns are still poorly understood and only rarely considered in snow hydrology (Lanini et al, 2009).…”
Section: Introductionmentioning
confidence: 99%