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Ongoing climate change has the potential to negatively impact Alaska’s ecosystems and the critical services that they provide. These ecosystem services include supplying food and fiber for Alaskan communities, offering opportunities for recreational, cultural, and spiritual activities, and regulating temperature and water flow (runoff, flooding, etc.). Scientists build models to better understand processes and interactions in the natural environment and to use what we know to predict what will happen in the future, so that we can plan for it. Researchers from multiple institutions and disciplines developed an Integrated Ecosystem Model (IEM) for Alaska and Northwest Canada. The model helps forecast how climate...
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The western coastline of Alaska is highly susceptible to coastal storms, which can cause erosion, flooding, and saltwater storm surge, affecting natural ecosystems, human communities, and commercial activity. Historically, a large buffer of ice along the shoreline has protected this region from some of the more severe effects of coastal storms. However, climate change may not only increase the frequency and intensity of storms, but also cause a loss of shoreline ice, possibly increasing the incidence of coastal erosion and flooding and introducing saltwater to freshwater environments. These hazards have the potential to substantially disrupt the environment and commerce in the region, but more information is needed...
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This project was designed to use climate models to produce projections of changes in sea temperatures and ocean chemistry for coastal marine areas in Micronesia as well as reports that describe the outlook of culturally important marine sites in Guam and CNMI. The projections and maps were expected show what the current state of climate science suggests the future holds for marine areas in Micronesia if we continue to use fossil fuels aggressively. These projections of sea conditions will become the foundation of outlook reports for Tumon Bay in Guam, Lao Lao Bay and Saipan Lagoon in Saipan, and northern Tinian Island. The selected areas are among the most important sites for recreation in Guam and CNMI and, as...
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Surrounded by saltwater, Hawaiian communities depend on freshwater streams for consumption, irrigation, traditional Hawaiian practices, and habitat for native fish and other stream life. It is important to be able to predict how Hawaiʻi’s streams will be affected by changing rainfall patterns to enable sustainable management of critical freshwater resources. However, to date, limited data and the uncertain effects of climate change have hindered predictions of future streamflow. Through this project, scientists developed a model that provides a way to estimate future stream low flow (streamflow during a period of prolonged dryness) by categorizing streams based on their physical characteristics. While the model...
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The Republic of the Marshall Islands (RMI) spreads over 29 atolls and has a population of over 50,000 people; over 27,000 of those people live on the Majuro Atoll, RMI’s capital. Sea level rise threatens the very existence of RMI as high-end projections of sea level rise by the end of the century exceed the average elevation of these low atoll reef islands. Already, waves wash over Majuro during “king tides” when strong winds blow from the west across the broad lagoon, or when there are high open ocean waves. Flooding waves breach island shores in multiple locations and wash into homes, cemeteries, across roads, and into commercial districts. Over the past decade, there has been a widespread exodus of residents...
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One of the biggest challenges facing resource managers today is not knowing exactly when, where, or how climate change effects will unfold. In order to plan for this uncertain future, managers have begun to use a tool known as scenario planning, in which climate models are used to identify different plausible climate conditions, known as “scenarios”, for a particular area. In a previous project, researchers with the North Central Climate Science Center worked with natural resource managers at Badlands National Park and on surrounding federal lands to model how different climate scenarios and management activities would impact the area’s resources. The model that was developed answers critical “what if” questions...
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The goal of this project was to identify climate-related scientific information needs in the North Central region that will support the management of key species and help avoid species declines. Researchers worked closely with state fish and wildlife agencies, the U.S. Fish and Wildlife Service, tribes, and other relevant natural resource management and conservation agencies to identify priority information needs and to design and implement studies that will address these needs. Researchers identified stakeholders, including those engaged by the North Central Climate Science Center USGS Liaisons project. Researchers worked with stakeholders to identify priority conservation targets. Selected targets were those...
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The loss or decline of culturally significant plants is a major concern for many tribal managers. Culturally significant plants are essential to many aspects of life for tribal members, including medicine, ceremonial practices, and traditional food dishes. In many parts of the U.S., droughts, floods, and changes in the timing of frost events are stressing these plants and in some cases have led to decreases in their areas of suitable habitat or a reduction in their resistance to disease. The goal of this project is to hold a research symposium that will bring together tribal resource managers and scientists from a range of disciplines in the South Central region to identify which culturally significant species...
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Currently, maintaining appropriate flows to support biological integrity is difficult for larger riverine ecosystems. Climate change, through increased temperature, reduced rainfall, and increased rainfall intensity, is expected to reduce water availability and exacerbate the maintenance of ecological flows in the Arkansas-Red River basin. Understanding the nexus among climate change effects on streamflow, water quality, and stream ecology for watersheds in the Arkansas-Red River Basin can be achieved using currently existing science and technology. This nexus approach will strengthen adaptive-management strategies that focus on shared ecosystem conservation watershed targets. This approach will provide natural-resource...
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Resource managers must balance the impacts of competing management decisions on multiple, interacting natural systems. Hydrologic and ecological processes, such as groundwater fluctuations and riparian evapotranspiration, can be tightly coupled. Ideally, managers would have tools and models that include all processes to better understand how each management action would propagate through the environment. Because resources are limited, management tools that include only the most important processes may be more realistic. However, in some cases, omitting some interactions can lead to significant errors in predictions of hydrologic outcomes and ecological function, severely limiting a manager’s ability to identify...
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Pinyon pine woodlands are among the most widespread and iconic vegetation types in the western United States and support recreation, resource extraction, grazing, and cultural enrichment. However, severe drought conditions have recently caused dramatic mortality of pinyon pines, creating concern about the long-term impact of increasing aridity on the viability of pinyon woodlands. Ecological transformations, or regime shifts, are rapid reorganizations of an ecosystem’s species composition, governing processes, and functions. The goal of this project is to investigate ecological transformation across the Western U.S, characterize the environmental drivers of these changes in vegetation, and apply those insights...
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In the Pacific Northwest, land and resource managers strive to make decisions that benefit both natural and human communities, balancing ecological and economic demands including wildlife habitat, forest products, forage for grazing, clean water, and wildfire control. Climate change adds a layer of complexity to the planning process because of its uncertain effects on the environment. In order to make sound decisions, managers need information about how climate change will affect wildlife habitat, both on its own and in conjunction with management actions. The goal of this project was to explore how future climate may interact with management alternatives to shape wildlife habitat across large landscapes. Scientists...
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Many animal species have unique characteristics that allow them to survive during winter. For example, the snowshoe hare changes its fur color from brown to white to camouflage better in winter months, and the ruffed grouse roosts under the snow to stay warm and hidden in winter. These winter-adapted species, however, are facing new challenges as climate change is resulting in shorter winters and rapid declines in snowpack. Shorter winters pose a significant threat to winter-adapted species that are used to living in, under, or on top of a protective blanket of snow. Wildlife managers are tasked with conserving these species, yet studies understanding how specific management actions can enhance species' ability...
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Habitat fragmentation, modification, and loss have been implicated in the decline of many species, including more than 85% of those considered threatened or endangered. Therefore, connectivity, or the ability of organisms to move among habitat patches, is a critical component of landscape health. In addition to influencing the sustainability of wildlife populations and communities, connectivity also contributes to the availability of ecosystem services. The goal of this project was to evaluate terrestrial connectivity across the South Central United States, with a focus on the impact of projected climate and land use changes. The researchers addressed this goal using a variety of approaches, including evaluating...
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The San Francisco Bay estuary contains the largest remaining expanse of tidal salt marshes in the western U.S. These marshes are home to a variety of federal and state protected species, such as the California clapper rail, California black rail, and the salt marsh harvest mouse. The estuary is also located on the Pacific Flyway, and is an important site for migrating and wintering birds. As climate conditions change, these salt marshes face a number of threats, including accelerated rates of sea-level rise, shifting precipitation, erosion, and more frequent and intense storms. Seas in the San Francisco Bay estuary have been rising 2.2 centimeters per decade, and could rise by as much as 1.24 meters by 2100, according...
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Quaking aspen populations are declining in much of the West due to altered fire regimes, competition with conifers, herbivory, drought, disease, and insect outbreaks. Aspen stands typically support higher bird biodiversity and abundance than surrounding habitat types, and maintaining current distribution and abundance of several bird species in the northern Great Basin is likely tied to the persistence of aspen in the landscape. This project examined the effects of climate change on aspen and associated bird communities by coupling empirical models of avian-habitat relationships with landscape simulations of vegetation community and disturbance dynamics under various climate change scenarios. Field data on avian...
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This project built on an existing regional conservation partnership to use the most recent downscaled climate model projections to forecast the likely impacts of climate change to species and ecosystems in the Lower Mississippi Valley (LMV). The objective of this work was to develop and test ecological and biological models to facilitate regional adaptive management of wildlife resources and the forest and wetland ecosystems that support them in the LMV. The modeled projections were then used to evaluate climate change effects on high priority bird species, waterfowl, amphibians, and fisheries. In particular, the researchers sought to answer two key questions: (1) what are the impacts of predicted climate change...
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A large portion of the U.S. population lives in coastal areas along the Atlantic and Gulf coasts and the Caribbean; however, our coasts are also home to many fish, wildlife, and plant species that are important for recreation, tourism, local economies, biodiversity, and healthy coastal ecosystems. Coastal habitats also provide protective ecosystem services to human communities, which are increasingly at risk to storms and sea level rise under future climate change. Understanding how climate change will impact natural and human communities is a crucial part of decision making and management related to the protection of our coasts. In a collaborative project between the North Atlantic Landscape Conservation Cooperative...
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Prairie ecosystems and the grassland birds that rely on them for habitat may be particularly vulnerable to rapid changes in climate. Extensive portions of prairie have already been lost due to agriculture and urbanization, and as a result grassland birds have declined more than any other bird group in the last four decades. Now, climate change could exacerbate existing threats to these birds as temperatures in certain prairie ecosystems are expected to rise and extreme weather events, such as drought, could become more common. The goal of this project was to develop a framework to identify demographic sensitivities and assess the vulnerability of grassland bird species to future climate change. To do so, the researchers...
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Climate change will have sweeping impacts across the Northeast, yet there are key gaps in our understanding about whether species will be able to adapt to this changing environment. Results from this project will illuminate local and region-wide changes in forest ecosystems by studying the red-backed salamander, a species that is a strong indicator of forest conditions. This study identified habitat and forest characteristics that improve the resiliency of forest dwelling amphibians and other wildlife to climate change. Further, by studying a foundational species in forest floor ecosystems, the scientists can use the information to make inferences about rare and declining species. The researchers studied multiple...
map background search result map search result map Fate of Endangered Species in San Francisco Bay Tidal Marshes with Sea-Level Rise Quantifying Vulnerability of Quaking Aspen Woodlands and Associated Bird Communities to Global Climate Change in the Northern Great Basin Climate, Land Management and Future Wildlife Habitat in the Pacific Northwest Terrestrial Connectivity Across the South Central United States: Implications for the Sustainability of Wildlife Populations and Communities Understanding the Impacts of Permafrost Change: Providing Input into the Alaska Integrated Ecosystem Model Modeling Western Alaska Coastal Hazards Forecasting the Effects of Land-Use and Climate Change on Wildlife Communities and Habitats in the Lower Mississippi Valley Assessing the Vulnerability of Grassland Bird Populations to Climate Change Understanding the Nexus between Climate, Streamflow, Water Quality, and Ecology in the Arkansas-Red River Basin Modeling the Response of Hawaiʻi’s Streams to Future Rainfall Conditions Understanding the Future of Red-Backed Salamanders as an Indicator of Future Forest Health Assessing the Sustainability of Culturally Important Marine Sites in Guam and CNMI Assessing the Impacts of Restoration Efforts on Water and Natural Systems in a Changing World Identifying Critical Thresholds and Tipping Points for Priority Coastal Species in a Changing Future Simulating and Projecting Future Impacts of Sea Level Rise on Majuro Atoll Enabling Climate-Informed Planning and Decisions about Species of Conservation Concern in the North Central Region: Phase 1 Informing Climate Change Adaptation Planning in National Parks Mapping the Risk of Ecological Transformation Across Pinyon Woodlands and the U.S. West Research Symposium: Culturally Significant Plants and Climate Change Managing and Promoting the Resiliency of Winter-Adapted Species to Climate Change Simulating and Projecting Future Impacts of Sea Level Rise on Majuro Atoll Informing Climate Change Adaptation Planning in National Parks Quantifying Vulnerability of Quaking Aspen Woodlands and Associated Bird Communities to Global Climate Change in the Northern Great Basin Assessing the Sustainability of Culturally Important Marine Sites in Guam and CNMI Modeling the Response of Hawaiʻi’s Streams to Future Rainfall Conditions Forecasting the Effects of Land-Use and Climate Change on Wildlife Communities and Habitats in the Lower Mississippi Valley Climate, Land Management and Future Wildlife Habitat in the Pacific Northwest Understanding the Nexus between Climate, Streamflow, Water Quality, and Ecology in the Arkansas-Red River Basin Managing and Promoting the Resiliency of Winter-Adapted Species to Climate Change Modeling Western Alaska Coastal Hazards Research Symposium: Culturally Significant Plants and Climate Change Enabling Climate-Informed Planning and Decisions about Species of Conservation Concern in the North Central Region: Phase 1 Terrestrial Connectivity Across the South Central United States: Implications for the Sustainability of Wildlife Populations and Communities Understanding the Future of Red-Backed Salamanders as an Indicator of Future Forest Health Mapping the Risk of Ecological Transformation Across Pinyon Woodlands and the U.S. West Identifying Critical Thresholds and Tipping Points for Priority Coastal Species in a Changing Future Assessing the Vulnerability of Grassland Bird Populations to Climate Change Understanding the Impacts of Permafrost Change: Providing Input into the Alaska Integrated Ecosystem Model