Publications
Filters: First Letter Of Last Name is L [Clear All Filters]
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2017. Climate Change and Hydrology in the Blue Mountains. Climate Change Vulnerability and Adaptation in the Blue Mountains Region. PNW GTR-939:22-33.
(32.66 MB)
(32.66 MB).
2019. Climate Change, Water, and Roads in South-Central Oregon. Climate Change Vulnerability and Adaptation in South Central Oregon.. :55-94. (35.54 MB)
(35.54 MB).
2019. Climate Change, Water, and Roads in South-Central Oregon. Climate Change Vulnerability and Adaptation in South Central Oregon.. :55-94. (35.54 MB)
(35.54 MB).
2019. Climate Change, Water, and Roads in South-Central Oregon. Climate Change Vulnerability and Adaptation in South Central Oregon.. :55-94. (35.54 MB)
(35.54 MB).
2017. Climate Change, Water Resources, and Roads in the Blue Mountains. Climate Change Vulnerability and Adaptation in the Blue Mountains Region. PNW-GTR-939:53-90.
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2006. Climate Variability, Snowmelt Distribution, and Effects on Streamflow in a Cascades Watershed. Eastern Snow Conference. :51-54. (427.09 KB)
(427.09 KB).
2010. Coevolution of hydrology and topography on a basalt landscape in the Oregon Cascade Range, USA. Earth Surface Processes and Landforms. :803-816. (1.43 MB)
(1.43 MB).
2010. Coevolution of hydrology and topography on a basalt landscape in the Oregon Cascade Range, USA. Earth Surface Processes and Landforms. :803-816. (1.43 MB)
(1.43 MB).
2014. Comparing Large-Scale Hydrological Model Predictions with Observed Streamflow in the Pacific Northwest: Effects of Climate and Groundwater. Journal of Hydrometeorology. 15 (2.13 MB)
(2.13 MB).
2018. Connectivity as an Emergent Property of Geomorphic Systems. Earth Surface Processes and Landforms. (711.29 KB)
(711.29 KB).
2013. Coupling snowpack and groundwater dynamics to interpret historical streamflow trends in the western United States. Hydrological Processes. 27:655–668. (1.34 MB)
(1.34 MB).
2022. COVID-19 Impacts Highlight the Need for Holistic Evaluation of Research in the Hydrologic Sciences. Water Resources Research. 58 (435.88 KB)
(435.88 KB).
2022. COVID-19 Impacts Highlight the Need for Holistic Evaluation of Research in the Hydrologic Sciences. Water Resources Research. 58 (435.88 KB)
(435.88 KB).
2006. Debris dams and the relief of headwater streams. Geomorphology. 82:84-97. (959.5 KB)
(959.5 KB).
2014. Debris flow initiation in proglacial gullies on Mount Rainier, Washington. Geomorphology. 226:249-260. (3.15 MB)
(3.15 MB).
2013. Debris flows in glaciated catchments: a case study on Mount Rainier, Washington. Geology. M.S.:149.
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2017. Designing a network of critical zone observatories to explore the living skin of the terrestrial Earth. Earth Surface Dynamics. 5:841-860. (9.65 MB)
(9.65 MB).
2006. Determination of bank erodibility for natural and anthropogenic bank materials using a model of lateral migration and observed erosion along the Willamette River, Oregon, USA. River Research and Applications. 22:631-649. (476.56 KB)
(476.56 KB).
2019. Disentangling Effects of Forest Harvest on Long-term Hydrologic and Sediment Dynamics, Western Cascades, Oregon. Journal of Hydrology. 580 (12.5 MB)
(12.5 MB).
2018. Effects of climate change on hydrology and water resources in the Blue Mountains, Oregon, USA. Climate Services. (5.61 MB)
(5.61 MB).
1990. Effects of forest land use on watershed hydrology: a modeling approach.. The Northwest Environmental Journal. 6:414-415.
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2008. Effects of forest practices on peakflows and consequent channel response: a state-of-science report for western Oregon and Washington. General Technical Reports. PNW-GTR-760:76. (1.97 MB)
(1.97 MB).
2003. Effects of wood on debris flow runout in small mountain watersheds. Water Resources Research. 39:1168. (878.16 KB)
(878.16 KB).
2023. Envisioning a near-surface geophysics center for convergent science. EOS. (2.78 MB)
(2.78 MB).
2008. Experimental and field observations of breach dynamics accompanying erosion of Marmot cofferdam, Sandy River, Oregon. World Environmental and Water Resources Congress. (499.74 KB)
(499.74 KB)