Publications
Downstream effects of the Pelton-Round Butte Hydroelectric Project on bedload transport, channel morphology and channel-bed texture, Lower Deschutes River, Oregon. A Peculiar River. Water Science and Application 7:169-202. (2.14 MB)
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2003. Vulnerability of water supply from the Oregon Cascades to changing climate: Linking science to users and policy. Global Environmental Change. 21:110-122. (409.91 KB)
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2011. Hillslope Hydrology in Global Change Research and Earth System Modeling. Water Resources Research. 55:35. (7.38 MB)
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2019. Water within, moving through, and shaping the Earth's surface: Introducing a special issue on water in the critical zone. Hydrological Processes. 33:3146-3151. (359.28 KB)
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2019. Owyhee River intracanyon lava flows: Does the river give a dam? Geological Society of America Bulletin. (2.33 MB)
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2012. A watershed moment for western U.S. dams. WRR. 59 (267.15 KB)
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2023. Lessons from a Flooded Landscape. Science Findings. 1:5. (1.57 MB)
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1998. Clarifying muddy water: probing the linkages to municipal water quality. Science Findings. 59:6. (406.82 KB)
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2003. Geology as Destiny: Cold waters run deep in western Oregon. Science Findings. 49:6. (272.09 KB)
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2002. Seen one dam, seen 'em all?: The surprising story of the Deschutes River Science Findings. 25:6. (251.37 KB)
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2000. A comparison of stochastic models for generating daily precipitation at the H J Andrews Experimental Forest. Northwest Science. 69:318-329.
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1995. Shallow landslide delineation for steep forest watersheds based on topographic attributes and probability analysis. Terrain analysis: Principles and Applications. :311-329. (1.85 MB)
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2000. Comment on "A Distributed Hydrology-Vegetation Model for Complex Terrain" by Mark S. Wigmosta, Lance W. Vail, and Dennis P. Lettenmaier. Water Resources Research. 32:211-212. (119.85 KB)
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1996. Modeling snow accumulation and melt in mountain watersheds. 13th Conference on Hydrology.
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1998. Dam Removal in the United States: Emerging Needs for Science and Policy. EOS. 84:32-33. (253.71 KB)
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2003. .
2022. Does Lava Flow Like Water? Assessing Applications of Critical Flow Theory to Channelized Lava Flows JGR: Earth Surface. (4.5 MB)
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2022. Can lava flow like water? Applying hydraulic critical flow theory to measuring lava effusion rates GSA Connects; doi: 10.1130/abs/2022AM-381194.
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2022. New insights into lava flow dynamics and hazards from the 2018 eruption of Kilauea, Hawaii. GSA Connects; doi: 10.1130/abs/2022AM-381170.
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2022. Field Trip Guide to Mafic volcanism of the central Oregon Cascades - A volcanic, tectonic, hydrologic, and geomorphic journey. Scientific Investigations Report. :94p..
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2017. Linking environmental flows to sediment dynamics. Water Policy. 19:358-375. (598.3 KB)
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2017. Will we need to change the rules: assessing the implications of climate change for dam operations in Oregon's McKenzie River Basin. Water Resources Graduate Program. M.S.:125.
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2013. Scenario-based and scenario-neutral assessment of climate change impacts on operational performance of a multipurpose reservoir. Journal of the American Water Resources Association. (2.7 MB)
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2017. Recent periglacial debris flows from Mount Rainier, Washington. Water Resources Graduate Program. M.S.:125.
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2023.