Browsing by Subject "urban streams"
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Item Open Access Linking Urban Land Use to Aquatic Metabolic Regimes(2021-04-30) Kindley, SierraMetabolism is a foundational property of ecosystems, and the productivity of rivers determines their capacity to retain and transform nutrients as well as support biodiversity. Stream metabolism has been increasingly used to assess waterway health due to its relevance across sizes and types of streams, sensitivity to stressors, and ability to be measured continuously. Land use change can affect metabolism through numerous mechanisms, including hydrology, light regimes, and nutrients, which may respond to changes in land use at different scales. This study used existing high frequency metabolism records and geospatial data to examine relationships among measures of catchment and riparian condition and stream Gross Primary Production (GPP). The primary goals were to identify the mechanisms by which urbanization and land use change affect metabolism, the scales at which these drivers exert the most influence, and any variance present across regions. Quantifiable proxies for each mechanism were used to characterize and assess its effect on GPP response along an urban land use gradient and spatial scale. This study focused on small headwater streams located in mesic environments. The study area for this project included a collection of stream gage sites in the eastern United States, each of which is located east of 96 degrees west longitude and has a total catchment area of less than 26 square kilometers. Four primary regions of focus were selected based on their display of a complete urban gradient (low total percent urban area to high total percent urban area within the catchment) among stream gage sites: Atlanta metropolitan area, Kansas City metropolitan area, Mid-Atlantic region, and Washington D.C. metropolitan area. Overall, we found that watershed scale urban cover was weakly correlated with stream characteristics that affect metabolism. Total percent tree canopy cover appears to exert control over metabolism at the local reach scale, while total percent urban land cover, total percent imperviousness, and total road density do this at the whole watershed scale. In all cases, GPP was negligible above a threshold land cover, and the higher variance in GPP at low to moderate urbanization levels is controlled by local canopy. This suggests that metabolic regimes arise from processes at multiple scales. Differences in GPP among the four focal regions are likely due to differences in climate, impervious surface, and riparian canopy among urban areas. These findings suggest that effective interventions may require catchment scale efforts to preserve and restore hydrologic regimes as well as local interventions to improve riparian condition. This has implications for resource protection, mitigation, and future planning. Understanding the relative importance of these processes and the scales at which they affect streams is critical for environmental management decisions, including the conservation and rehabilitation of streams, as well as designing appropriate interventions. Ultimately, this project demonstrates how richer and larger datasets can expand our understanding and inform decision making at new scales. Future temporal scale analyses that assess the seasonality or disturbance recovery trajectories of these data may further benefit our understanding of these processes and relationships. Additionally, we suggest conducting comparative analyses of these data in terms of seasonal patterns and how temporal patterns differ between GPP and ecosystem respiration (ER).Item Open Access Linking Urban Land Use to Aquatic Metabolic Regimes(2021-04-30) Kindley, SierraMetabolism is a foundational property of ecosystems, and the productivity of rivers determines their capacity to retain and transform nutrients as well as support biodiversity. Stream metabolism has been increasingly used to assess waterway health due to its relevance across sizes and types of streams, sensitivity to stressors, and ability to be measured continuously. Land use change can affect metabolism through numerous mechanisms, including hydrology, light regimes, and nutrients, which may respond to changes in land use at different scales. This study used existing high frequency metabolism records and geospatial data to examine relationships among measures of catchment and riparian condition and stream Gross Primary Production (GPP). The primary goals were to identify the mechanisms by which urbanization and land use change affect metabolism, the scales at which these drivers exert the most influence, and any variance present across regions. Quantifiable proxies for each mechanism were used to characterize and assess its effect on GPP response along an urban land use gradient and spatial scale. This study focused on small headwater streams located in mesic environments. The study area for this project included a collection of stream gage sites in the eastern United States, each of which is located east of 96 degrees west longitude and has a total catchment area of less than 26 square kilometers or less. Four primary regions of focus were selected based on their display of a complete urban gradient (low total percent urban area to high total percent urban area within the catchment) among stream gage sites: Atlanta metropolitan area, Kansas City metropolitan area, Mid-Atlantic region, and Washington D.C. metropolitan area. Overall, we found that whole watershed scale urban cover was weakly correlated with stream characteristics that affect metabolism. Total percent tree canopy cover appears to exert control over metabolism at the local reach scale, while total percent urban land cover, total percent imperviousness, and total road density do this at the whole watershed scale. In all cases, GPP was negligible above a threshold land cover, and the higher variance in GPP at low to moderate urbanization levels is controlled by local canopy. This suggests that metabolic regimes arise from processes at multiple scales. Differences in GPP among the four focal regions are likely due to differences in climate, impervious surface, and riparian canopy among urban areas. These findings suggest that effective interventions may require catchment scale efforts to preserve and restore hydrologic regimes as well as local interventions to improve riparian condition. This has implications for resource protection, mitigation, and future planning. Understanding the relative importance of these processes and the scales at which they affect streams is critical for environmental management decisions, including the conservation and rehabilitation of streams, as well as designing appropriate interventions. Ultimately, this project demonstrates how richer and larger datasets can expand our understanding and inform decision making at new scales. Future temporal scale analyses that assess the seasonality or disturbance recovery trajectories of these data may further benefit our understanding of these processes and relationships. Additionally, we suggest conducting comparative analyses of these data in terms of seasonal patterns and how temporal patterns differ between GPP and ER.Item Open Access Pattern and Variation in Development of Small Urban Watersheds(2014-04-25) Allen, Diane MaryIncreased urbanization has been correlated with hydrologic, chemical, geomorphologic, and biologic changes to receiving streams. Therefore, the status quo in watershed management has been to control the amount of impervious surface area. However, because various measures of development and impervious surface area are correlated, it is hard to discern what aspects of development cause adverse ecological impacts: impervious surface area is correlated with stormwater infrastructure, natural vegetation cover, road density, and so on. In practice, the level of variability in any of these parameters can be high at any intensity of development. We can take advantage of that variability to choose landscape configurations that minimize watershed impacts for any given level of urbanization. To do so, we must understand how watershed land cover parameters co-vary with development intensity (percent impervious surface) and which aspects of configuration most directly impact urban streams. To this end, I examined 14 specific aspects of development configuration and stormwater infrastructure for 235 small watersheds in the Piedmont region of North Carolina. For both landscape metrics and infrastructure features, there was a high degree of variability at almost any level of development intensity. In the case of road density for central ranges of development, there was so much variation that the expected positive correlation of roads with development was no longer significant. Our results set the stage for future exploration of the hydrologic and chemical processes that are altered in urban streams. Relation of development pattern to ecological process in this way will support more nuanced methods for management of watershed development so that hydrologic impacts might be minimized for any given level of development intensity.