Brian A. Ebel
(He/him)Brian Ebel is a Research Hydrologist for the USGS Water Resources Mission Area.
Brian Ebel is a hydrologist who uses field measurements combined with numerical modeling to advance prediction and assessment for water resources through improved process representation. His work focuses on landscape disturbance impacts (e.g., wildfire, forestry, legacy mining) on water availability and water-related hazards to human lives and infrastructure. He was awarded the Presidential Early Career Award for Scientists and Engineers (PECASE) in 2019 for his contributions to understanding post-wildfire flooding and water availability issues. In 2023, Brian was selected as a Kavli Fellow by the National Academy of Sciences. Brian is currently in the Earth System Processes Division of the USGS Water Resources Mission Area.
Professional Experience
2014-present: Research Hydrologist, U.S. Geological Survey, Water Mission Area
2013-2014: Research Assistant Professor, Colorado School of Mines
2012-2013: Research Assistant Professor, University of Colorado-Boulder
2008-2012: Hydrologist, U.S. Geological Survey, Water Resources Mission Area
Education and Certifications
Stanford University, Ph.D. in Hydrogeology
Washington University in St. Louis, B.A. in Earth and Planetary Science
Science and Products
Hydrologic conditions controlling runoff generation immediately after wildfire
Impact of wildfire and slope aspect on soil temperature in a mountainous environment
Wildfire impacts on soil-water retention in the Colorado Front Range, United States
Assessing the detail needed to capture rainfall-runoff dynamics with physics-based hydrologic response simulation
Hydraulic Property and Soil Textural Classification Measurements for Rainier Mesa, Nevada Test Site, Nevada
The quixotic search for a comprehensive understanding of hydrologic response at the surface: Horton, Dunne, Dunton, and the role of concept-development simulation
Estimation of Unsaturated Zone Traveltimes for Rainier Mesa and Shoshone Mountain, Nevada Test Site, Nevada, Using a Source-Responsive Preferential-Flow Model
First-order exchange coefficient coupling for simulating surface water-groundwater interactions: Parameter sensitivity and consistency with a physics-based approach
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
Science and Products
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Filter Total Items: 56
Hydrologic conditions controlling runoff generation immediately after wildfire
We investigated the control of postwildfire runoff by physical and hydraulic properties of soil, hydrologic states, and an ash layer immediately following wildfire. The field site is within the area burned by the 2010 Fourmile Canyon Fire in Colorado, USA. Physical and hydraulic property characterization included ash thickness, particle size distribution, hydraulic conductivity, and soil water retAuthorsBrian A. Ebel, John A. Moody, Deborah A. MartinImpact of wildfire and slope aspect on soil temperature in a mountainous environment
Soil temperature changes after landscape disturbance impact hydrology, ecology, and geomorphology. This study used field measurements to examine wildfire and aspect effects on soil temperatures. Combustion of the litter and duff layers on north-facing slopes removed pre-fire aspect-driven soil temperature controls.Wildfire is one of the most significant disturbances in mountainous landscapes and cAuthorsBrian A. EbelWildfire impacts on soil-water retention in the Colorado Front Range, United States
This work examined the plot-scale differences in soil-water retention caused by wildfire in the area of the 2010 Fourmile Canyon Fire in the Colorado Front Range, United States. We measured soil-water retention curves on intact cores and repacked samples, soil particle-size distributions, and organic matter content. Estimates were also made of plant-available water based on the soil-water retentioAuthorsBrian A. EbelAssessing the detail needed to capture rainfall-runoff dynamics with physics-based hydrologic response simulation
Concept development simulation with distributed, physics-based models provides a quantitative approach for investigating runoff generation processes across environmental conditions. Disparities within data sets employed to design and parameterize boundary value problems used in heuristic simulation inevitably introduce various levels of bias. The objective was to evaluate the impact of boundary vaAuthorsB.B. Mirus, B.A. Ebel, C.S. Heppner, K. LoagueHydraulic Property and Soil Textural Classification Measurements for Rainier Mesa, Nevada Test Site, Nevada
This report presents particle size analysis, field-saturated hydraulic conductivity measurements, and qualitative descriptions of surficial materials at selected locations at Rainier Mesa, Nevada. Measurements and sample collection were conducted in the Rainier Mesa area, including unconsolidated sediments on top of the mesa, an ephemeral wash channel near the mesa edge, and dry U12n tunnel pond sAuthorsBrian A. Ebel, John R. NimmoThe quixotic search for a comprehensive understanding of hydrologic response at the surface: Horton, Dunne, Dunton, and the role of concept-development simulation
[No abstract available]AuthorsK. Loague, C.S. Heppner, B.A. Ebel, J.E. VanderKwaakEstimation of Unsaturated Zone Traveltimes for Rainier Mesa and Shoshone Mountain, Nevada Test Site, Nevada, Using a Source-Responsive Preferential-Flow Model
Traveltimes for contaminant transport by water from a point in the unsaturated zone to the saturated zone are a concern at Rainier Mesa and Shoshone Mountain in the Nevada Test Site, Nevada. Where nuclear tests were conducted in the unsaturated zone, contaminants must traverse hundreds of meters of variably saturated rock before they enter the saturated zone in the carbonate rock, where the regionAuthorsBrian A. Ebel, John R. NimmoFirst-order exchange coefficient coupling for simulating surface water-groundwater interactions: Parameter sensitivity and consistency with a physics-based approach
Distributed hydrologic models capable of simulating fully-coupled surface water and groundwater flow are increasingly used to examine problems in the hydrologic sciences. Several techniques are currently available to couple the surface and subsurface; the two most frequently employed approaches are first-order exchange coefficients (a.k.a., the surface conductance method) and enforced continuity oAuthorsB.A. Ebel, B.B. Mirus, C.S. Heppner, J.E. VanderKwaak, K. LoagueNon-USGS Publications**
Ebel, B. A., 2013, Simulated unsaturated flow processes after wildfire and interactions with slope aspect, Water Resources Research, 49, 8090–8107, doi: 10.1002/2013WR014129Loague, K., and , B. A. Ebel, 2013, Conceptualization in catchment modeling. In Treatise on Geomorphology, Edited by J. F. Shroder, Vol. 7, pp. 105-121. San Diego, Academic Press, doi: 10.1016/B978-0-12-374739-6.00154-8Ebel, B. A., K. Loague, and R. I. Borja, 2010, The impacts of hysteresis on variably-saturated hydrologic response and slope failure, Environmental Earth Sciences, 61, 1215-1225, doi: 10.1007/s12665-009-0445-2BeVille, S. H., B. B. Mirus, B. A. Ebel, G. G. Mader, and K. Loague, 2010, Using simulated hydrologic response to revisit the 1973 Lerida Court landslide, Environmental Earth Sciences, 61, 1249-1257, doi: 10.1007/s12665-010-0448-zEbel, B. A., K. Loague, D. R. Montgomery, and W. E. Dietrich, 2008, Physics-based continuous simulation of long-term near-surface hydrologic response for the Coos Bay experimental catchment, Water Resources Research, 44, W07417, doi:10.1029/2007WR006442Ebel, B. A., and K. Loague, 2008, Rapid simulated hydrologic response within the variably saturated near surface, Hydrological Processes, 22, 464-471, doi:10.1002/hyp.6926
Ebel, B. A., K. Loague, W. E. Dietrich, D. R. Montgomery, R. Torres, S. P. Anderson, and T. W. Giambelluca, 2007, Near-surface hydrologic response for a steep, unchanneled catchment near Coos Bay, Oregon: 1. Sprinkling experiments, American Journal of Science, 307, 678-708, doi:10.2475/04.2007.02Ebel, B. A., K. Loague, J. E. VanderKwaak, W. E. Dietrich, D. R. Montgomery, R. Torres, and S. P. Anderson, 2007, Near-surface hydrologic response for a steep, unchanneled catchment near Coos Bay, Oregon: 2. Physics-based simulations, American Journal of Science, 307, 709-748, doi:10.2475/04.2007.03Mirus, B. B., B. A. Ebel, K. Loague, and B. C. Wemple, 2007, Simulated effect of a forest road on near-surface hydrologic response: Redux, Earth Surface Processes and Landforms, 32, 126–142, doi: 10.1002/esp.1387Ebel, B. A., and K. Loague, 2006, Physics-based hydrologic-response simulation: Seeing through the fog of equifinality, Hydrological Processes, 20, 2887–2900, doi:10.1002/hyp.6388
Borja, R. I., G. Oettl, B. Ebel, and K. Loague, 2006, Hydrologically driven slope failure initiation in variably saturated porous media. In Modern Trends in Geomechanics. Wu, W. and H.S. Yu (Eds.), pp. 303-311, Springer-Verlag, Berlin Heidelberg, doi: 10.1007/978-3-540-35724-7_18Loague, K., C. S. Heppner, B. B. Mirus, B. A. Ebel, Q. Ran, A. E. Carr, S. H. BeVille, and J. E. Vander Kwaak, 2006, Physics-based hydrologic-response simulation: foundation for hydroecology and hydrogeomorphology, Hydrological Processes, 20, 1231–1237, doi:10.1002/hyp.6388
Ehlmann, B. L., R. E. Arvidson, B. L. Jolliff, S. S. Johnson, B. Ebel, N. Lovenduski, J. D. Morris, J. A. Byers, N. O. Snider, and R. E. Criss, 2005, Hydrologic and Isotopic Modeling of Alpine Lake Waiau, Mauna Kea, Hawai‘i, Pacific Science, 59, 1–15, doi:10.1353/psc.2005.0005
Loague, K., C. S. Heppner, R. H. Abrams, A. E. Carr, J. E. VanderKwaak, and B. A. Ebel, 2005, Further testing of the Integrated Hydrology Model (InHM): event-based simulations for a small rangeland catchment located near Chickasha, Oklahoma, Hydrological Processes, 19, 1373–1398, doi:10.1002/hyp.5566**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.