Browsing by Subject "Stream"
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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 Assessing the Potential of Creating a Stream Mitigation Bank on the Tar River(2015-04-24) Yang, Cha; Yang, NuoerDevelopment projects discharging fill material into any U.S. navigable waters require approval under Section 404 of the Clean Water Act, and must show that steps were taken to avoid environmental impacts. Unavoidable impacts require compensatory action to mitigate environmental loss. Mitigation banking serves as an outlet to provide compensatory mitigation to offset those environmental impacts on streams and wetlands. The Tar River Land Conservancy, a land trust in North Carolina focused on preserving the natural ecosystem on the Tar River basin, is interested in the prospectus of creating a mitigation bank. Three main objectives of the project include 1) identifying and ranking sites suitable for a mitigation bank, 2) conducting a literature review to determine liabilities/pitfalls of mitigation banking and develop recommendations to overcome the challenges, and 3) identifying elemental factors to creating a sustainable business plan that also contributes to the mission of the land trust. The findings aim to assist the decision-making process for the client to ascertain the potential of pursing the business endeavor.Item Open Access Changes in stream ecosystem structure as a function of urbanization: Potential recovery through stream restoration(2007-05) Cada, PeterI documented reach scale changes in the physical structure of 12 stream channels in the summer months of 2006, comparing four small streams draining forested catchments with eight streams from developed watersheds of similar catchment size. Study sites in four of the urban streams are within recently implemented natural channel design restoration projects. To assess whether restoration projects increase stream habitat and flow heterogeneity and increase water exchange with floodplain and hyporheic sediments I compared reach-scale geomorphic (e.g. slope, cross section, degree of incision, variation in water depth) and hydrologic (e.g. transient storage volume (TS), surface-water groundwater exchange, fine scale variation in velocity) features of each stream. I used ArcGIS to compile watershed maps and to produce detailed maps of reach habitat for each stream, and the hydrologic model OTIS-P to estimate transient storage from field rhodamine releases. Minimally impacted reaches were found to have shallower average depths with a greater variation in depth than urban or restored stream reaches. Streams restored to provide habitat had the lowest flow habitat heterogeneity of the three stream classes. Channel incision was the only physical channel feature for which the urban restored streams were more similar to the forested streams than the urban degraded condition. Surprisingly, I was unable to detect significant differences in transient storage volume or hyporheic exchange between our three stream classes. My results suggest that restoration designs are placing inadequate attention on recreating the physical template seen in less degraded streams.Item Open Access Determining Stream and Wetland Health in an Urban Restored Riparian Ecosystem in Durham NC through Benthic-macroinvertebrate Surveys(2014-04-24) Howington, JessieWater and aquatic habitat quality are frequently assessed by analyzing the structure of benthic macroinvertebrate communities in streams and other bodies of water. The Stream and Wetland Assessment Management Park (SWAMP) in Durham, NC, part of Sandy Creek, is a restored stream and wetland complex started in 2003. Restoration phases have been constructed to target both improvements in water quality and habitat. The two focal phases of restoration for this project were a re-sculpting of the geomorphology of the main stem of Sandy Creek and the creation of a braided or anabranched stream pattern. The anabranching stream pattern allows stream water to frequently come in contact with the soils in the floodplains for a prolonged period, promoting beneficial biogeochemical processes. This project tested both the change in water and habitat quality over time, as well as the difference in water and habitat quality between the restoration phases. Chemical and microbial laboratory analyses have shown that the water quality has improved since the restoration. Benthic macroinvertebrate data over an 8-year period demonstrate dissimilar results. The macroinvertebrate community analysis shows an overall decrease in both water and habitat quality since the restoration. There is also a significant difference in the macroinvertebrate communities found between restoration phases, specifically, the stream channel in the anabranching phase is shown to have lower water and habitat quality than that of the main stem. These findings are contrary to the expected results for a stream and wetland restoration project, but may be due to unusually high stream discharges in 2013 compared to earlier survey periods.Item Open Access The Role of Riparian Wetland Restoration in Amphibian Conservation(2011-09-02) Anderson, CatherineThe worldwide decline in amphibian populations may be a harbinger of ecosystem degradation. Wetland and stream restoration may counter amphibian population declines by increasing habitat quality, area, and connectivity. Among the causes of amphibian declines, habitat loss and fragmentation are some of the most influential mechanisms contributing to species extinction. Connectivity between streams and riparian wetlands are not only important for stormwater and water quality management, but are also essential for the conservation and management of amphibians. Even with the dramatic expansion of stream and riparian wetland restoration projects nationwide, post-restoration monitoring of the effectiveness of restoration rarely includes assessment of wildlife populations. Assessment of population declines and restoration success requires long-term monitoring. However, long-term amphibian population studies are relatively few in North America and particularly lacking in North Carolina. The effects of integrated stream and wetland restoration on frogs and toads in the North Carolina Piedmont were analyzed, focusing on the Duke University Wetland Center Stream and Wetland Assessment Management Park (SWAMP). Anuran communities were compared in restored and reference riparian wetlands using drift fence and pitfall trap arrays along with auditory surveys. A total of 100 individual amphibians and eight species were detected in traps between summer 2010 and summer 2011. Ten species were detected with auditory monitoring, including three species heard but not seen. Mann-Whitney tests were used to assess differences among amphibian abundance at restored and reference sites. Mantel tests were used to assess dissimilarity of sites based on species composition. Neither relative abundance nor species richness estimates were significantly different among restored and reference sites, although community composition did differ by restoration status. Differences in community composition did include overlap, however, and future monitoring based on the protocol established in this study should reveal population trends over time. In addition to the SWAMP project’s specific goal of improving water quality, the restored streams and adjacent wetlands are also supporting frog and toad populations similar to those in natural riparian wetlands.Item Open Access Understanding Effects of Anthropogenic Activities on Element Cycling in Temperate Forest Watersheds(2011) Lutz, BrianHuman activities are increasingly altering the ways in which energy and elements cycle within and move between ecosystems. Through fossil fuel combustion and the use of synthetic fertilizers we continue to expose much of the biosphere to new rates and ratios of essential element supply. We are also shifting climate patterns on local, regional and global scales in ways that affect reaction rates and residence times of elements within ecosystems. Even the simplest ecosystems are usually too complex to predict many of the potential consequences that human activities will have on their sustained functioning. Because of this, we often monitor ecosystems as integrated wholes, looking to explain processes that account for important patterns observed across space and time. This dissertation consists of 3 data chapters, all of which use the small watershed ecosystem as the principal unit of study for understanding how human activities have altered element cycling in temperate forests in the southern Appalachian Mountains.
In Chapter 2, we present results from repeated synoptic surveys of streamwater chemistry for ~30 watersheds spanning one of the largest nitrogen (N) deposition gradients in North America, located within the Great Smoky Mountains National Park. We primarily focus on patterns in dissolved organic matter (DOM) concentrations and composition across the N gradient, with particular attention given to dissolved organic nitrogen (DON). DON dominates the global flux of N between terrestrial and aquatic systems, yet we have little understanding of how this prevailing N form responds to human N pollution. We found that DON concentrations often declined significantly with increasing catchment N loading and, through laboratory bioavailability assays, found that when N limitation is alleviated increased microbial demand for labile carbon (C) may drive this pattern. We use these findings to suggest a new hypothesis for the potential responses of DON to anthropogenic N pollution that accounts for the dual role that DON plays in both C and N cycles.
Chapter 3 is an extension of Chapter 2, in which we attempt to assess the role of DON as either a C or N source within an entire stream reach through a series of independent manipulations of labile C and inorganic N availabilities. In the second order reach of Walker Branch, a well-studied stream in eastern Tennessee, we performed a series of progressive (i.e., sequentially increasing concentrations), kinetic (i.e., very short duration), enrichments of acetate and nitrate on two successive days during April of 2009 before the tree canopy emerged and when in-stream algal production was high. In this system and on these short timescales, we were unable to elicit the same responses observed at sites across the chronic N deposition gradient in Chapter 2. We did, however, observe that DOM processing and composition was significantly altered. Using fluorescence characterization of DOM, we found that adding acetate displaced heterotrophic demand for terrestrially derived DOM. Conversely, nitrate additions stimulated production of highly bioavailable autochthonous DOM within the stream channel, which resulted in an indirect displacement of demand for terrestrially derived DOM. Understanding DOM dynamics in streams has long been a priority for stream ecologists because it represents an important energy and nutrient source fueling stream metabolism. Our results provide new insight into the processes controlling DOM concentrations and composition in Walker Branch, as well as demonstrate the potential of this method for future investigations of DOM in stream ecosystems.
Chapter 4 deviates from the preceding chapters' focus on N availability and ecosystem DOM dynamics, instead assessing the role of climate change on long-term streamwater concentrations and fluxes from the West Fork of the Walker Branch watershed. At this site, mean annual temperatures have increased by ~2˚C, while mean annual precipitation and runoff have declined by ~20% and >40%, respectively, since 1989. We use weekly streamwater samples to assess trends in concentrations and fluxes for 9 different solutes over this period and, using wet deposition data, also evaluate changes in approximate watershed input-output budgets. The observed change in runoff was accompanied by a change in the proportional contributions of different soil flowpaths to streamflow generation through time, with deep groundwater playing an increasingly important role in recent years. Solutes that increase in concentration deeper in the soil profile exhibited significant increases in streamwater concentrations through time, while solutes with higher concentrations in soil solution in the upper profile decreased in concentration. Nutrient solutes, which exhibit much less variation across soil flowpaths, typically display large seasonal patterns in streamwater concentrations that are driven by in-stream biological uptake. However, most nutrient solutes exhibited little or no trend in concentrations through time, indicating that the biological controls on these solutes have remained relatively unaltered by the observed changes in climate over the 20-year period. On shorter timescales, changes in the frequency or severity of multi-year droughts, as well as changes in the frequency or intensity of storms that disrupt in-stream uptake, can have large impacts on watershed input-output budgets of nutrient solutes even if the effects do not manifest as linear trends through time. Our results demonstrate the important role that changing climates can have on watershed element cycles, illustrating that climate effects can manifest through either changes in hydrologic regime or through changing biogeochemical process rates.
Taken together, these chapters illustrate that human activities are indirectly but substantially changing biogeochemical cycles in temperate forests throughout the Southern Appalachians. Ecosystem structure and function depends on the ways in which energy and elements move within and between ecosystems. We rely on the sustained integrity of ecosystems for their many services and, because of this, it is essential that we understand ecosystem responses to current and future human impacts.