Your search keyword '"Keith, Mackenzie K."' showing total 5 results

1. Historical Changes to Channel Planform and Bed Elevations Downstream from Dams Along Fall Creek and Middle Fork Willamette River, Oregon, 1926-2016.

Author

Keith, Mackenzie K., Wallick, J. Rose, Gordon, Gabriel W., and Bervid, Heather D.

Subjects

STREAMFLOW, RIVER channels, GEOMORPHOLOGY, SEDIMENT transport

Abstract

Operation of large, multipurpose dams within the Middle Fork Willamette River Basin, Oregon, including the Fall Creek sub-basin, have disrupted natural streamflow and sediment transport regimes and fish passage along the river corridors. Documenting channel morphology, including channel planform, landforms, vegetation cover, and river channel elevations at multiple points in time spanning the 20th and early 21st centuries, is useful for characterizing net changes occurring in response to construction and operation of these dams. The U.S. Geological Survey assessed historical channel changes that occurred within the past century in response to the construction and operation of flood-control dams by evaluating planimetric datasets (from 1926 plan and profile surveys and 1936 and 2016 aerial photographs) and elevation datasets (from 1926 plan and profile surveys and 2015 light detection and ranging [lidar]). This study specifically focuses on the lower 27.3 kilometers (km) of the Middle Fork Willamette River and the lower 11.5 km of Fall Creek, or the reaches downstream from the U.S. Army Corps of Engineers Dexter Dam and Fall Creek Dam, to the confluence with Coast Fork Willamette River. Altogether, compilation and evaluation of datasets for Fall Creek and the Middle Fork Willamette River downstream from the dams provide a foundation for understanding: 1. channel morphology and patterns of geomorphic stability prior to dam construction in 1926 and 1936; 2. channel morphology and patterns of lateral and vertical stability of the early 21st century that reflect present-day (post-dam) streamflow and sediment regimes as of 2015-16; and 3. geomorphic transformations of the river corridors in the decades following dam construction, including changes in planform and bed elevation (determined from water-surface elevations). Findings from this study can be used to provide historical and geomorphic context for geomorphic responses to deep reservoir drawdowns on Fall Creek Lake that mobilize reservoir sediment downstream and informing other restoration and river-management activities; this report summarizes one component of a larger research effort to document the magnitude and spatial distribution of geomorphic responses to sediment releases from draining Fall Creek Lake. As of 2016, the modern Fall Creek flows through a narrow, semi-alluvial channel that efficiently conveys water and sediment at typical streamflows downstream from Fall Creek Dam. This channel planform, including the positions and distributions of bars and secondary water features (side channels, alcoves, and ponds), generally reflects pre-dam conditions in 1936, suggesting relatively modest morphological adjustments resulted from reductions in sediment supply and alterations to peak streamflow after dam construction. The most substantial morphologic change detected over this period was a reduction in unvegetated gravel bars. As of 2016, the modern Middle Fork Willamette River is a large, gravel-bed river that, despite substantial transformations in channel morphology and reduction in lateral dynamism following the construction of multiple upstream dams, remains a dominantly alluvial river. Prior to dam construction in 1926 and 1936, the reaches of the Middle Fork Willamette River downstream from Dexter Dam were laterally active with multi-thread and single-thread channels flanked by large, shifting gravel bars. Since streamflow regulation and other channel modifications in the mid-20th century, these reaches have become less laterally active and encompass a narrower floodplain corridor as abundant former gravel bars were converted to low-elevation floodplains colonized by young, dense forests. The Middle Fork Willamette River downstream from Dexter Dam has remained mostly vertically stable between 1926 and 2015, although localized segments possibly decreased in elevation as much as 2.3 meters. [ABSTRACT FROM AUTHOR]

Published

2023

2. River Network and Reach‐Scale Controls on Habitat for Lamprey Larvae in the Umpqua River Basin, Oregon.

Author

Jones, Krista L., Dunham, Jason B., O'Connor, Jim E., Keith, Mackenzie K., Mangano, Joseph F., Coates, Kelly, and Mackie, Travis

Published

2020

3. Monitoring Framework to Evaluate Effectiveness of Aquatic and Floodplain Habitat Restoration Activities for Native Fish along the Willamette River, Northwestern Oregon.

Author

Keith, Mackenzie K., Wallick, J. Rose, Flitcroft, Rebecca L., Kock, Tobias J., Brown, Laura A., Miller, Rich, Hagar, Joan C., Guillozet, Kathleen, and Jones, Krista L.

Subjects

NATIVE fishes, GOVERNMENT agencies, GEOLOGICAL mapping, SEDIMENTATION & deposition

Published

2022

4. Monitoring Framework for Evaluating Hydrogeomorphic and Vegetation Responses to Environmental Flows in the Middle Fork Willamette, McKenzie, and Santiam River Basins, Oregon.

Author

Wallick, J. Rose, Bach, Leslie B., Keith, Mackenzie K., Olson, Melissa, Mangano, Joseph F., and Jones, Krista L.

Subjects

FLOODPLAIN ecology, WATERSHEDS, AERIAL photographs, CHINOOK salmon

Published

2018

5. GIS Database and Discussion for the Distribution, Composition, and Age of Cenozoic Volcanic Rocks of the Pacific Northwest Volcanic Aquifer System Study Area.

Author

Sherrod, David R. and Keith, Mackenzie K.

Subjects

VOLCANIC ash, tuff, etc., GEOGRAPHIC information systems, GEOLOGICAL mapping, HYDROGEOLOGICAL modeling

Abstract

A substantial part of the U.S. Pacific Northwest is underlain by Cenozoic volcanic and continental sedimentary rocks and, where widespread, these strata form important aquifers. The legacy geologic mapping presented with this report contains new thematic categorization added to state digital compilations published by the U.S. Geological Survey for Oregon, California, Idaho, Nevada, Utah, and Washington (Ludington and others, 2005). Our additional coding is designed to allow rapid characterization, mainly for hydrogeologic purposes, of similar rocks and deposits within a boundary expanded slightly beyond that of the Pacific Northwest Volcanic Aquifer System study area. To be useful for hydrogeologic analysis and to be more statistically manageable, statewide compilations from Ludington and others (2005) were mosaicked into a regional map and then reinterpreted into four main categories on the basis of (1) age, (2) composition, (3) hydrogeologic grouping, and (4) lithologic pattern. The coding scheme emphasizes Cenozoic volcanic or volcanic-related rocks and deposits, and of primary interest are the codings for composition and age. [ABSTRACT FROM AUTHOR]

Published

2018