The following pages link to Deborah Martin (Q140039):
Displayed 28 items.
- Soil-water dynamics and unsaturated storage during snowmelt following wildfire (Q147275) (← links)
- Preserving geomorphic data records of flood disturbances (Q147821) (← links)
- Synthesising empirical results to improve predictions of post-wildfire runoff and erosion response (Q153292) (← links)
- Wildland fire ash: Production, composition and eco-hydro-geomorphic effects (Q154671) (← links)
- Initial hydrologic and geomorphic response following a wildfire in the Colorado front range (Q157424) (← links)
- Hydrologic and Erosion Responses of Burned Watersheds (Q228308) (← links)
- The role of precipitation type, intensity, and spatial distribution in source water quality after wildfire (Q234174) (← links)
- Editorial: The role of ash in fire-affected ecosystems (Q234937) (← links)
- At the nexus of fire, water and society (Q238284) (← links)
- Meta-analysis of field-saturated hydraulic conductivity recovery following wildland fire: Applications for hydrologic model parameterization and resilience assessment (Q239650) (← links)
- Current research issues related to post-wildfire runoff and erosion processes (Q244522) (← links)
- Effects of a low severity prescribed fire on water-soluble elements in ash from a cork oak (Quercus suber) forest located in the northeast of the Iberian Peninsula (Q250827) (← links)
- Post-fire temporal trends in soil-physical and -hydraulic properties and simulated runoff generation: Insights from different burn severities in the 2013 Black Forest Fire, CO, USA (Q259199) (← links)
- Relations between soil hydraulic properties and burn severity (Q261033) (← links)
- Can pore-clogging by ash explain post-fire runoff? (Q267914) (← links)
- Linking fire and the United Nations Sustainable Development Goals (Q269854) (← links)
- Eighteen years (1996-2014) of channel cross-sectional measurements made in Spring Creek after the 1996 Buffalo Creek wildfire and subsequent flood (Q270936) (← links)
- Thresholds and relations for soil‐hydraulic and soil‐physical properties as a function of burn severity 4 years after the 2011 Las Conchas Fire, New Mexico, USA (Q280318) (← links)
- Wildfire-driven changes in hydrology mobilize arsenic and metals from legacy mine waste (Q280746) (← links)
- A call for strategic water-quality monitoring to advance assessment and prediction of wildfire impacts on water supplies (Q281162) (← links)
- Fire, flood, and drought: Extreme climate events alter flow paths and stream chemistry (Q282222) (← links)
- Fire, forests and city water supply (Q294089) (← links)
- Chapter 4. Predicting post-fire erosion and sedimentation risk on a landscape scale (Q294652) (← links)
- Hydrologic conditions controlling runoff generation immediately after wildfire (Q303557) (← links)
- Influence of extreme and annual floods on point-bar sedimentation: Inferences from Powder River, Montana, USA (Q303642) (← links)
- Chemistry of water, stream sediment, wildfire ash, soil, dust, and mine waste for Fourmile Creek Watershed, Colorado, 2010-2019 (Q329076) (← links)
- Water chemistry data for Fourmile Creek Watershed, 2010-2015 (Q330279) (← links)
- Soil-physical and soil-hydraulic properties as a function of burn severity for 2013, 2015, and 2017 in the area affected by the 2013 Black Forest Fire, Colorado USA (Q330292) (← links)