Browsing by Subject "Dam"
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Item Open Access A GIS Tool Prioritizing Dams for Removal within the State of North Carolina(2012-04-27) Hoenke, KathleenA GIS tool for prioritizing removal of dams based on ecological and social metrics is presented. The Barrier Prioritization Tool uses a hierarchical decision making framework that entails identification of an objective, criteria of qualities that meet that objective, and measurable indicators to quantify if criteria is met. Here the primary objective is to identify the best dams to remove. Criteria include good habitat connectivity, good water quality connectivity and connectivity of stream miles while avoiding social conflict, improving flow downstream, and improving safety. Sensitivity of rankings to habitat indicators used indicates that indicators of habitat quality overlap. Following the construction of the Barrier Prioritization Tool, three prioritization scenarios are conducted for American Rivers; one prioritization includes social and safety criteria, another includes only ecological criteria, and the third is a prioritization specific to anadromous fish. All three of these prioritization scenarios identify dams within the top 20 ranked dams that are currently classified as pre-identified potential dam-removal projects, indicating that the tool is performing as intended. Dam removal has proven to be an effective mechanism of quickly restoring in-stream habitat for lotic species through connecting fragmented river networks and returning the system to a free flowing state. By aiding in the dam removal project identification process, this tool makes the restoration of streams through dam removal more efficient. In the future, this tool will be used by American Rivers and their colleagues to run other prioritizations of the tool while experimenting with different indicator and criteria weights in order to find more potential projects for removal.Item Open Access Habitat loss, alteration, and fragmentation in river networks: Implications for Freshwater Mussels and Their Landscape Genomics(2017) Fuller, Matthew RobertThis dissertation focuses on the implications of habitat change in freshwater ecosystems. Habitat change has three primary components that are inextricably connected; habitat loss, alteration, and fragmentation. Habitat loss is the physical removal and/or replacement of “core” habitat such that a new “matrix” habitat exists in its place. Habitat alteration is the modification of core habitat that causes a quality change (either positive or negative depending on the target species). Habitat fragmentation affects the connectivity between core habitat patches in the landscape. Rivers are highly fragmented both naturally and anthropogenically, so they represent a system readily available to study the impacts of habitat change on ecosystems.
Four approaches were used to evaluate the impacts of habitat change on freshwater ecosystems. First (Chapter 1 as published in the Annals of the New York Academy of Sciences with co-authors Dr. Martin Doyle and Dr. David Strayer; see Fuller et al. (2015)), a review of the major causes and consequences of habitat change in river networks was conducted with the goal of also bridging a theoretical gap between terrestrial and freshwater systems related to habitat change ecology. Second (Chapter 2), an empirical evaluation of a fragmented (dammed) river reach was used to evaluate the local impacts of habitat loss and alteration on physical (sediment), biogeochemical (dissolved oxygen), and biological (freshwater mussels) response variables. Third (Chapter 3), gene flow model simulations were used to identify the genetic impacts of habitat fragmentation at the river-network scale. This simulation effort contrasted the impact of habitat fragmentation with species longevity to see how organisms using different life history strategies related to lifespan respond genetically to habitat fragmentation. Fourth (Chapter 4), an empirical landscape genomics evaluation of a species of freshwater mussel (Elliptio complanata) was conducted to identify its genetic response to a river network with a long history of habitat change.
Conclusions from this research make several contributions to the ecological theory of habitat change. First, by applying the habitat change lexicon in terrestrial systems to freshwater systems, sharing results and theory across the terrestrial-aquatic literature becomes simple and may advance the theory behind habitat change ecology more rapidly with more empirical results to draw upon. Second, temporally dynamic matrix habitat and species capitalizing on altered edge habitat were identified surrounding a local habitat fragmentation agent (a dam), suggesting some species may strongly benefit from the presence of edge habitat in river networks. Third, from the gene flow model simulations, the life history of a species played an important role in how organisms respond genetically to habitat fragmentation where long-lived species appear buffered from the genetic diversity loss caused by habitat fragmentation. Finally, the empirical evaluation of a freshwater mussel species that has experienced a long history of anthropogenic-driven habitat change via water quality alterations, inundation losses, and dam fragmentation appears to have maintained a population genetic structure unrelated to the expected habitat change in the system.