158 results on '"Theobald, David M."'
Search Results
152. Why Study Climate Change in Wildlands?
- Author
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Hansen, Andrew J., Hansen, Andrew J., editor, Monahan, William B., editor, Olliff, S. Thomas, editor, and Theobald, David M., editor
- Published
- 2016
- Full Text
- View/download PDF
153. Effectively Linking Climate Science and Management
- Author
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Gross, John E., Olliff, S. Thomas, Hansen, Andrew J., editor, Monahan, William B., editor, Olliff, S. Thomas, editor, and Theobald, David M., editor
- Published
- 2016
- Full Text
- View/download PDF
154. Achieving climate connectivity in a fragmented landscape.
- Author
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McGuire, Jenny L., Lawler, Joshua J., McRae, Brad H., Nuñez, Tristan A., and Theobald, David M.
- Subjects
- *
FRAGMENTED landscapes , *CLIMATE & zoogeography , *BIOLOGICAL evolution , *HABITATS , *NATURAL landscaping - Abstract
The contiguous United States contains a disconnected patchwork of natural lands. This fragmentation by human activities limits species' ability to track suitable climates as they rapidly shift. However, most models that project species movement needs have not examined where fragmentation will limit those movements. Here, we quantify climate connectivity, the capacity of landscape configuration to allow species movement in the face of dynamically shifting climate. Using this metric, we assess to what extent habitat fragmentation will limit species movements in response to climate change. We then evaluate how creating corridors to promote climate connectivity could potentially mitigate these restrictions, and we assess where strategies to increase connectivity will be most beneficial. By analyzing fragmentation patterns across the contiguous United States, we demonstrate that only 41% of natural land area retains enough connectivity to allow plants and animals to maintain climatic parity as the climate warms. In the eastern United States, less than 2% of natural area is sufficiently connected. Introducing corridors to facilitate movement through human-dominated regions increases the percentage of climatically connected natural area to 65%, with the most impactful gains in low-elevation regions, particularly in the southeastern United States. These climate connectivity analyses allow ecologists and conservation practitioners to determine the most effective regions for increasing connectivity. More importantly, our findings demonstrate that increasing climate connectivity is critical for allowing species to track rapidly changing climates, reconfiguring habitats to promote access to suitable climates. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
155. Mapping global land conversion pressure to support conservation planning.
- Author
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Oakleaf J, Kennedy C, Wolff NH, Terasaki Hart DE, Ellis P, Theobald DM, Fariss B, Burkart K, and Kiesecker J
- Subjects
- Humans, Ecosystem, Biodiversity, Conservation of Natural Resources
- Abstract
Proactively identifying where land conversion might occur is critical to targeted and effective conservation planning. Previous efforts to map future habitat loss have largely focused on forested systems and have been limited in their consideration of drivers of loss. We developed a 1-km resolution, global map of land conversion pressure from multiple drivers, referred to as the conversion pressure index (CPI). The CPI combines past rates of anthropogenic change, as measured by temporal human modification maps, with suitability maps for potential future expansion by large-scale development. The CPI thus offers a new way to measure a cumulative gradient of anthropogenic pressure as opposed to categorical land cover change. We find that nearly 23% of land across 200 countries have relatively high conversion pressure, potentially impacting over 460 million ha of intact natural lands. We illustrate how this information can be used to identify areas for proactive conservation to avoid future loss and ensure that national commitments under the Kunming-Montreal Global Biodiversity and Paris Agreement Climate Frameworks are upheld., (© 2024. The Author(s).)
- Published
- 2024
- Full Text
- View/download PDF
156. Evaluating ecosystem protection and fragmentation of the world's major mountain regions.
- Author
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Theobald DM, Jacob AL, Elsen PR, Beever EA, Ehlers L, and Hilty J
- Subjects
- Altitude, Conservation of Natural Resources methods, Biodiversity, Ecosystem
- Abstract
Conserving mountains is important for protecting biodiversity because they have high beta diversity and endemicity, facilitate species movement, and provide numerous ecosystem benefits for people. Mountains are often thought to have lower levels of human modification and contain more protected area than surrounding lowlands. To examine this, we compared biogeographic attributes of the largest, contiguous, mountainous region on each continent. In each region, we generated detailed ecosystems based on Köppen-Geiger climate regions, ecoregions, and detailed landforms. We quantified anthropogenic fragmentation of these ecosystems based on human modification classes of large wild areas, shared lands, and cities and farms. Human modification for half the mountainous regions approached the global average, and fragmentation reduced the ecological integrity of mountain ecosystems up to 40%. Only one-third of the major mountainous regions currently meet the Kunming-Montreal Global Biodiversity Framework target of 30% coverage for all protected areas; furthermore, the vast majority of ecosystem types present in mountains were underrepresented in protected areas. By measuring ecological integrity and human-caused fragmentation with a detailed representation of mountain ecosystems, our approach facilitates tracking progress toward achieving conservation goals and better informs mountain conservation., (© 2024 The Authors. Conservation Biology published by Wiley Periodicals LLC on behalf of Society for Conservation Biology. This article has been contributed to by U.S. Government employees and their work is in the public domain in the USA.)
- Published
- 2024
- Full Text
- View/download PDF
157. Exposure of U.S. National Parks to land use and climate change 1900-2100.
- Author
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Hansen AJ, Piekielek N, Davis C, Haas J, Theobald DM, Gross JE, Monahan WB, Olliff T, and Running SW
- Subjects
- Adaptation, Physiological, Animals, Human Activities, Humans, Introduced Species, Models, Theoretical, Time Factors, United States, Climate Change, Conservation of Natural Resources methods, Ecosystem
- Abstract
Many protected areas may not be adequately safeguarding biodiversity from human activities on surrounding lands and global change. The magnitude of such change agents and the sensitivity of ecosystems to these agents vary among protected areas. Thus, there is a need to assess vulnerability across networks of protected areas to determine those most at risk and to lay the basis for developing effective adaptation strategies. We conducted an assessment of exposure of U.S. National Parks to climate and land use change and consequences for vegetation communities. We first defined park protected-area centered ecosystems (PACEs) based on ecological principles. We then drew on existing land use, invasive species, climate, and biome data sets and models to quantify exposure of PACEs from 1900 through 2100. Most PACEs experienced substantial change over the 20th century (> 740% average increase in housing density since 1940, 13% of vascular plants are presently nonnative, temperature increase of 1 degree C/100 yr since 1895 in 80% of PACEs), and projections suggest that many of these trends will continue at similar or increasingly greater rates (255% increase in housing density by 2100, temperature increase of 2.5 degrees-4.5 degrees C/100 yr, 30% of PACE areas may lose their current biomes by 2030). In the coming century, housing densities are projected to increase in PACEs at about 82% of the rate of since 1940. The rate of climate warming in the coming century is projected to be 2.5-5.8 times higher than that measured in the past century. Underlying these averages, exposure of individual park PACEs to change agents differ in important ways. For example, parks such as Great Smoky Mountains exhibit high land use and low climate exposure, others such as Great Sand Dunes exhibit low land use and high climate exposure, and a few such as Point Reyes exhibit high exposure on both axes. The cumulative and synergistic effects of such changes in land use, invasives, and climate are expected to dramatically impact ecosystem function and biodiversity in national parks. These results are foundational to developing effective adaptation strategies and suggest policies to better safeguard parks under broad-scale environmental change.
- Published
- 2014
- Full Text
- View/download PDF
158. The role of geographic information systems in wildlife landscape epidemiology: models of chronic wasting disease in Colorado mule deer.
- Author
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Farnsworth ML, Hoeting JA, Hobbs NT, Conner MM, Burnham KP, Wolfe LL, Williams ES, Theobald DM, and Miller MW
- Abstract
The authors present findings from two landscape epidemiology studies of chronic wasting disease (CWD) in northern Colorado mule deer (Odocoileus hemionus). First, the effects of human land use on disease prevalence were explored by formulating a set of models estimating CWD prevalence in relation to differences in human land use, sex and geographic location. Prevalence was higher in developed areas and among male deer suggesting that anthropogenic influences (changes in land use), differences in exposure risk between sexes and landscape-scaled heterogeneity are associated with CWD prevalence. The second study focused on identifying scales of mule deer movement and mixing that had the greatest influence on the spatial pattern of CWD in north-central Colorado. The authors hypothesised that three scales of mixing - individual, winter subpopulation and summer subpopulation - might control spatial variation in disease prevalence. A fully Bayesian hierarchical model was developed to compare the strength of evidence for each mixing scale. Strong evidence was found indicating that the finest mixing scale corresponded best to the observed spatial distribution of CWD prevalence. This analysis demonstrates how information on the scales of spatial processes that generate observed patterns can be used to gain insight into the epidemiology of wildlife diseases when process data are sparse or unavailable.
- Published
- 2007
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