Browsing by Subject "Land use"
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Item Open Access 1 Linking Land Use and Water Quality: Guiding Development Surrounding Durham County’s Drinking Watershed(2012-04-26) Levin, Katie RoseAbstract Linking Land Use and Water Quality: Guiding Development Surrounding Durham County’s Drinking Watershed By Katie Rose Levin May 2012 Cities and Counties have an obligation to provide water to their citizens in the quality and quantity necessary to support a viable existence. To meet these demands, in 1929 Durham City dammed the Flat River, creating the reservoir named “Lake Michie” in the far north eastern part of Durham County. Although located in a primarily rural area, there are signs that stormwater runoff is having detrimental effects on Lake Michie. The reservoir has already lost a quarter of its holding capacity to sedimentation, and was recently classified as Eutrophic by the USGS. Development pressure will only increase, as for the last ten years Durham County’s population has grown faster than the average across the state. To address development concerns, Durham county and city created the Unified Development Ordinance (UDO) which provides enhanced protection for the land in the Lake Michie Watershed. The UDO limits the amount of impervious surface allowed on any one parcel in the watershed to 6%, while allowing a transfer of development between parcels to discourage urban sprawl. In addition to the protection afforded by codes, Durham managers are interested in creating a unified conservation scheme, based on preserving parcels as forested areas. This Project provides information and maps that can be used for conservation planning. Through combining topography, soils, and land use, areas likely to have highest impact on water quality are highlighted. Using this information, parcels can be evaluated based on their relative impact on water quality. Likewise, parcels can be compared against each other for the relative impact they have on water quality, informing transfers of impervious surface areas to meet development code. By combining the scientific evaluation of land use effects with the political boundaries of parcel ownership officials can easily translate science into the politics of conservation and development. Just like the New Hope Creek and Eno River conservation maps, now Lake Michie has a scientifically based conservation map to help officials and land managers preserve water quality into the future. Adviser: Dr. Dean UrbanItem Open Access Classification of stream biological condition within the Chesapeake Bay watershed(2009-04-25T04:39:46Z) Talal, Michelle LeeHuman land use activities at the landscape scale are increasingly the largest threat to the biological condition of watershed and stream ecosystems. The Chesapeake Bay watershed (CBW), a particularly valuable watershed within the United States, has undergone considerable land use change over the past 400 years and faces many restoration challenges. Using fish indicators of biological integrity (IBIs), and data for land use, land cover, and environmental attributes, five empirical models (CART model, Random Forest, Conditional Tree, Conditional Forest, and ordinal logistic regression) were used to predict the biological condition of 1st-3rd order streams within the CBW. After the models were evaluated using resubstitution and 10-fold cross validation, the highest performing model was identified (Random Forest) and extrapolated to 71,182 stream sites within the CBW using geographic information software (GIS). Of these sites, 49% (35,006 sites) were classified as having “Good” biological condition, 24% (16,826 sites) as having “Fair” biological condition, and 27% (19,350 sites) as having “Poor” biological condition. The variable importance plot generated by the Random Forest (RF) model showed that watershed area (upslope of sampling location, km2) was the most important variable, followed by percentage of impervious surface cover, and percentage of pasture cover. Additionally, the Random Forest’s partial dependence plots showed the marginal effect of each variable on the class probability. As watershed area (km2) increases, there is a higher probability of a “fair” or “good” classification of stream biological condition; with a threshold watershed area of approximately 20 – 25 km2. Also, as the percentage of impervious surface cover increases, there is a greater probability of a poor classification of stream condition (threshold of ~5% impervious surface cover). The results of this study may help environmental and land use managers understand the effects of human land use and make more effective land use decisions to address watershed impairment within the CBW.Item Open Access Development and Land Use Impacts on Marine Ecosystems in the United States Virgin Islands (USVI)(2017-04-25) Rohrs, SuzanneAnthropogenic and natural stressors have long been a source of concern as they relate to water quality and marine ecosystem health, particularly in the United States Virgin Islands (USVI). Although many studies have been conducted in the USVI on factors influencing near-shore ecosystems, most are concentrated on just one or two inputs leaving data gaps. By conducting a meta-analysis of available long-term data produced by different organizations in ArcGIS, correlations between the following factors were observed: 1) land use 2) development 3) water quality and 4) coral health. In areas with a high percentage of land development, lower water quality and reduced live coral cover were observed at corresponding time scales. The results indicate the importance of linking multiple parameters to overall ecosystem health in order to develop focused management strategies to protect fragile near-shore environments.Item Open Access Examine Agricultural Land Use Practices and Their Effects on Carbon Storage and Flux in the United States(2022-04-22) Wang, Hongyi; Luo, ZhixianThe terrestrial ecosystem has provided a net carbon sink, equal to 20% of total greenhouse gas (GHG) emission from industrial activities in the past three decades, yet many land use activities, mainly agriculture, can drastically change natural land carbon flux. We worked with Resources for the Future (RFF) on the Carbon and Land Use Model (CALM) that helps with evaluating the effects of policy decisions on land use and relevant carbon flux changes. To evaluate potential approaches for estimating accurate carbon fluxes from agricultural land use practices, our team first conducted literature review to ascertain carbon flux from different land use changes along with detailed examination of the EPA GHG Emission inventory report 2021 and the 2006 IPCC Guidelines for National Greenhouse Gas Inventories. Then, we identified and assessed data knowledge gaps in existing methods of emission estimation and carbon fluxes modeling. Finally, recommendations were provided to RFF on how the CALM model can be further developed and utilized.Item Open Access Expected carbon emissions from a rubber plantation in Central Africa(Forest Ecology and Management, 2021-01-15) Jong, Ying Wei; Beirne, Christopher; Meunier, Quentin; Mekui Biyogo, Andréana Paola; Ebang Mbélé, Alex; Stewart, Christopher G; Poulsen, John RThe development of agriculture on degraded lands is increasingly seen as a strategy to boost food availability and economic productivity while minimizing environmental degradation and loss of forests. To understand the effects of agricultural production on forest carbon, we quantify the aboveground carbon (AGC) of a degraded forest in northeast Gabon (the Olam Rubber Gabon concession) designated for development to a rubber plantation. Combining field measurements from 19 1-ha tree plots and aerial LiDAR, we estimate forest AGC stocks and emissions under four development scenarios: no development, 30-year rubber rotation, extended rubber rotation (replanting of plantation in stages at 30 and 40 years), and 30-year oil palm rotation. On average, the degraded forest in the study area stored 123.8 Mg C ha−1, a mean AGC lower than the Gabon average (141.6 Mg C ha−1) but substantially higher than the 75 Mg C ha−1 threshold recommended by the High Carbon Stock protocol. Converting secondary forest to plantation might incur high environmental opportunity costs from lost carbon sequestration through forest succession and growth. In this study, we estimate that a rubber plantation can sequester similar amounts of AGC as secondary forest by the end of a 30-year rotation; however, the time-averaged AGC of regenerating secondary forests under no development would be 184% higher than a mature rubber plantation with a 30-year rotation, 169% higher than an extended rubber rotation, and 512% higher than a 30-year oil palm rotation. When degraded forest is developed for agriculture, measures should be taken to avoid emissions and prolong carbon retention. We specifically estimate carbon retention from extended harvest rotations and conserving high carbon value areas as set-asides and highlight recommendations from the literature such as minimizing soil disturbance and creating rubber timber products (e.g. furniture). To minimize carbon emissions from agriculture, crop plantation area should be minimized at national and regional scales in highly forested countries, and new plantations should be coupled explicitly with effective forest restoration actions, through suitable regulation and planning, to mitigate or compensate for their climate and biodiversity impacts.Item Open Access Impacts of Land Use on Mobile Source CO2 Emissions(2008-04-25T16:41:26Z) Carr, AllisonThe issue of mobile source emissions has not been as prominent as energy efficiency or renewable energy in the national climate policy debate. This analysis examines the potential impact of land use patterns on carbon dioxide emissions from mobile sources. Specifically, this report addresses the CO2 emissions of non-road construction equipment and light-duty passenger vehicles associated with sustainable land use patterns and urban sprawl. As local governments and developers begin to plan and take action to reduce CO2 emissions, tools will be needed to quantify emission reductions associated with local land use patterns. The objective of this project is to provide an inventory tool in Microsoft Excel that calculates the magnitude of emissions from construction and highway vehicles associated with various land use patterns.Item Open Access Land Use and Conservation Plan for the Stone House(2011-04-28) McHugh, Maureen; Spitzig, Adam; Tuggle, AshleyThe Stone House is a property owned and maintained by the non-profit organization stone circles located in Mebane, NC. The organization’s mission is to “sustain activists and strengthen the work of justice through spiritual practice and principles.” They are committed to ensuring that their 70 acres of land benefit the local community, regional ecosystem, and the global environmental movement. The purpose of this master’s project was to create a land use and conservation plan for stone circles that incorporates the organization’s many visions for the site, as well as recommends sources of funding to reduce current management costs. To this end, the staff of stone circles helped us to identify their needs and limitations by posing questions that ultimately shaped how the plan addressed the following issues: (1) the management of onsite vegetation and wildlife habitat, (2) the expansion of organic food production, (3) the establishment of an educational trail system, (4) onsite stormwater management with particular attention toward erosion control, and (5) feasibility, costs, and funding of various management scenarios. Several land use and funding options were explored for the stone circles property including: obtaining a conservation easement, using the back field as a wetland mitigation bank, using the field as a solar farm, leasing land for long-term residential use, leasing the field for agricultural use, and implementing the conservation and stormwater management plans that were developed. The conservation management plan involves permaculture improvements to the orchard, facilitating reforestation of the back field, installing a trail network, and the developing educational materials for onsite visitors. The recommended option for stone circles at this time is to implement the conservation and stormwater management plans. There are numerous funding streams available to assist in financing these plans, including governmental programs, grants, carbon offsets, and timber sales. A grant we have specifically applied for is the Rudolf Steiner Foundation Seed Grant. The estimated costs of the conservation management plan include: Reforestation: $0 - $9,450 Trail: $13,500 - $99,000 (conservative estimate) Signs: $72 - $1,350 In terms of stormwater management, the estimated costs for the plan include: Purchase of four rain barrels: $216 - $480 Installing one rain garden: $4,000 - $6,000 Improving riparian buffers: $0 - $7,600 Paving the road with a permeable grassy paver: $65,000 (paving materials alone) Implementing best management practices for the road: $10,000 (roadbed materials alone) Total costs to implement the conservation management plan range from $72 to $109,800 and the cost of implementing the stormwater management plan range from $0 to over $79,000 depending on which portions stone circles decides to implement and at what scale.Item Open Access Land Use Land Cover in the Western Ghats, India(2013-04-26) Gerlach, Paul; Hubbard, Malissa; Norment, ElizabethIn India’s Western Ghats mountain range, a UNESCO World Heritage Site and Conservation International biodiversity hotspot, human-caused habitat loss threatens many native species. A number of protected areas have been created to provide a refuge for these species and prevent further habitat loss. However, encroaching development continues to threaten these delicate ecosystems. Despite the area’s environmental value, there is no reliable, high-resolution land use land cover (LULC) map that would allow managers to estimate the extent and distribution of development as well as habitat condition and connectivity across the region. Using ASTER imagery, we conducted LULC classifications of 6 protected areas and their surroundings (20 km buffers). Separate classifications were conducted on Anshi-Dandeli National Park, Nagarahole and Bandipur National Parks, BRT Wildlife Sanctuary, and Kudremukh and Bhadra Wildlife Sanctuaries, for a total of four classification regions. We conducted both supervised maximum likelihood and unsupervised ISODATA classifications. Accuracy of the supervised classifications was higher than accuracy of the unsupervised classifications, with values ranging from 75.6-84.4%. Forest class accuracy ranged from 74% - 91%. We used the LULC classifications to assess the amount of forest cover within the protected areas and in the 20 km surrounding buffer. Within the classifications, 45-67% of the land is forested, while 17-35% of the land has been cleared for human use. We also conducted pilot analyses of forest fragmentation, patch connectivity, and human-affected areas in different parks. The LULC maps will be used to help managers set conservation goals and establish land use baselines for the region.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 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 Potomac Watershed Priority Lands Strategy: Conserving lands to benefit drinking water quality(2009-04-24T17:09:17Z) Weidner, EmilyRapid development in the Potomac watershed – the conversion of forests to agricultural, suburban, and urban land — threatens water quality. Similarly, strategic land conservation can protect water quality. Inspired by examples of water purification through land conservation, the EPA Region 3 and the Potomac River Basin Source Water Protection Partnership (PRBSWPP) aim to prioritize areas of the Potomac watershed for conservation. To work toward this goal, I analyzed two questions: (1) How do land areas in the Potomac Watershed support stream water quality?; and (2) In a larger context, how should land conservation be prioritized to protect water quality? To assess the relationship between land use and water quality, I created a regression model to correlate land characteristics including land use composition, land use pattern, and hydrological connectivity, with water quality. The final regression shows that buffer capacity (i.e. the average percentage of downstream forest area) has the largest impact on water quality, followed by urban saturation (i.e. average percentage of downstream urban area), and two estimates of soil loss and erodibility. I mapped the output of this regression analysis. To identify priority lands for conservation, I developed a multi-object decision analysis (MODA) tool. I used the weighted averaging approach to combine a land parcel’s water quality protection value, water intake protection value, and ecological value, along with its vulnerability to future development. This resulted in a map showing areas of higher and lower conservation priority, which can be used to allocate funds for conservation, update local zoning to designate strategically located natural areas, assist developers in minimizing their environmental impact, and strengthen coalitions in developing a common understanding of the multiple benefits of land conservation.Item Open Access Scaling Up Palm Oil Certification: Gaps and Options for More Sustainable Production(2010-04-30T02:13:59Z) Zuehlke, Robert T.Palm oil production is a rapidly growing commodity industry leading to rampant deforestation and land use change due to its lucrative financial returns. Palm oil plantation expansion has significant impacts on ecosystem services, biodiversity loss, and greenhouse gas balances through extensive logging activities and unsustainable land use change. Greater certification and sustainable production is necessary in order to not only lessen environmental impacts but also to ensure longer-term and more sustainable economic growth for producing regions. This report focuses on some of the fundamental economic aspects driving production processes and analyzes ways to implement more sustainable means of production and improve certification transparency throughout the supply chain. Improving field management and productive yields alongside expansion onto degraded land are two components of the scaling up of sustainable oil palm production. Viable mechanisms and incentives must address the profitability and opportunity costs of sustainable management practices and the cost of certification that oil palm producers face. The findings here illustrate the current gaps in incentivizing producers to undertake more sustainable processes. GreenPalm, Malua BioBank, tiered certification, payments for ecosystem services (PES) programs, Reducing Emissions from Deforestation and forest Degradation (REDD) activities, and higher price premiums for certified environmental goods are all potential ways to address the costs of certification and ensure more sustainable production. A combination of such innovative approaches with more robust governance and regulatory measures are critical catalysts that can help drive such change. Without sufficiently addressing opportunity costs, business-as-usual approaches will only continue, increasing environmental impacts and limiting the welfare of future generations in these regions.Item Open Access The Sustainable Palm Oil Puzzle: Evaluating Land Management Strategies for Forest Conservation and Climate Change Mitigation in the Global Palm Oil Industry(2018) Austin, KemenThis research evaluates the potential for regulatory measures governing oil palm plantation expansion, and corporate voluntary sustainability commitments in the oil palm industry, to contribute to forest protection and greenhouse gas emissions reduction goals at regional and national scales, using case studies from Indonesia and Gabon. Globally, agricultural production will need to increase by 60–110% by 2050, to meet anticipated demand for food, fiber and biofuels (Alexandratos and Bruinsma, 2012; Tilman et al., 2011). Achieving this increase without negative consequences for forests, biodiversity, and climate will require innovative solutions including increasing productivity, minimizing waste and inefficiencies, improving food distribution and access, shifting diet preferences, and optimizing land use (Foley et al., 2011; Godfray et al., 2010; Newton et al., 2013). Palm oil, which comprises 35% of global vegetable oil consumption, is emblematic of this challenge (Sayer et al., 2012). The production of palm oil is increasing more rapidly than any other oil crop, and an increasingly urban and wealthy global population is anticipated to drive further demand (Hertel, 2011). In Southeast Asia, where 87% of global palm oil production is currently concentrated, industrial-scale plantations nearly quadrupled in extent from 1990–2010 (Gunarso et al., 2013), and drove the conversion of millions of hectares of forest and peat lands (Carlson et al., 2013; Koh et al., 2011). There is therefore growing concern among environmental advocates that, if appropriate safeguards are not put in place, future expansion of oil palm cultivation will reflect historical patterns, leading to the continued destruction of biodiversity- and carbon-rich forest landscapes (Linder, 2013; Wich et al., 2014). In response to these concerns, government and private sector stakeholders have proposed or established policies aimed at minimizing the negative environmental consequences of oil palm production. Here, I investigate the potential impacts of these programs and policies by examining historical trends in industrial-scale oil palm plantation expansion patterns, predicting business-as-usual trajectories of future plantation expansion, and estimating the potential impacts of alternative policy scenarios on future plantation development, and on forests, peatlands, and carbon stocks. In Chapter 1, I provide background information on palm oil and its uses, cultivation requirements, production patterns, and documented environmental impacts. I additionally discuss actual or proposed government regulations and private sector sustainability initiatives that are relevant in the contexts of Indonesia and/or Gabon. In Chapter 2, I present an analysis of patterns of oil palm expansion, and impacts on forest and peat lands, in Indonesia from 1995–2015. In Chapter 3, I develop predictions of future Indonesian oil palm expansion under a range of policy scenarios, and provide estimates of the extent to which these scenarios will contribute to forest protection and concomitant CO2 emissions reductions. In Chapter 4, I evaluate the extent to which greenhouse gas emissions reductions in the oil palm sector will contribute to Indonesia’s national mitigation goals, given uncertainties in the current national greenhouse gas inventory system. In Chapter 5, I develop national suitability maps for oil palm cultivation in Gabon, a new frontier of oil palm expansion, and identify priority areas which have the potential to support production goals while protecting forest landscapes. Finally, I summarize findings across these studies, present next steps, and provide concluding remarks in Chapter 6.