Cameron L Aldridge, PhD
Dr. Cameron Aldridge is a research ecologist at the Fort Collins Science Center. Dr. Aldridge's work focuses on the conservation and management of sage-grouse and their habitats.
Dr. Cameron Aldridge is a Research Ecologist with the US Geological Survey, based at the Fort Collins Science Center, who works in collaboration with the Natural Resource Ecology Lab at Colorado State University. He is also an Affiliate Research Scientist at NREL and an Affiliate Professor with ESS and GDPE.
His research is diverse, but he is best recognized as one of the foremost sage-grouse ecologists in the world. He has a large research program focused on understanding the conservation and management of Greater and Gunnison Sage-grouse and their habitats. His research team includes both undergraduate and graduate students, research associates, post-doctoral fellows, and research scientists, all of which collaborate to understand why sage-grouse populations have declined, what major factors affect resource conditions and quality for sage-grouse, what drives population dynamics. The Aldridge Lab works closely on these issues with state and federal partners, as well as NGOs, conservation groups and industry.
More broadly, research in the Aldridge Lab involves understanding animal-habitat relationships, with an emphasis on conservation ecology and population demography. Researchers in the lab are addressing the effects of energy development, land-use change, and climate change on conserving wildlife populations, their habitats, and the ecosystems they inhabit. Species that we are currently studying include songbirds and small mammals, snakes and lizards, and grouse, such as white-tailed ptarmigan and sage-grouse. We also work with plant communities and exotic invasive plants, understanding how external drivers such as climate, grazing and energy development affect plant communities. We work across spatial scales, and use statistical and empirical modeling to answer these research and conservation questions, most of which have direct applications for conservation and management of the species and their habitats. Most of the research has direct applications for conservation and management of the species, most notably sage-grouse, and their habitats.
Professional Experience
August 2023-Present Branch Chief, and Research Supervisory Ecologist, Ecosystem and Landscape Dynamic Research Branch, US Geological Survey, Fort Collins Science Center, Fort Collins, Colorado.
March 2022-Present Acting Branch Chief, Ecosystem and Landscape Dynamic Research Branch, US Geological Survey, Fort Collins Science Center, Fort Collins, Colorado
Feb. 2020-Present Research Ecologist, US Geological Survey, Fort Collins Science Center, Fort Collins, Colorado
Feb. 2020-Present Affiliate Research Scientist, Natural Resource Ecology Laboratory, Colorado State University
Feb. 2020-Present Affiliate Professor, Department of Ecosystem Science and Sustainability and Graduate Degree Program in Ecology, Colorado State University
Jan. 2017-20 Finance Committee Member for the Natural Resource Ecology Laboratory, Colorado State University
July 2015-20 Associate Professor with Tenure, Department of Ecosystem Science and Sustainability, Colorado State University
July 2015-Present Research Scientist III, Natural Resource Ecology Laboratory, Colorado State University & U.S. Geological Survey, FORT Science Center, Fort Collins, Colorado
Aug. 2014-16 Executive Committee Member, Graduate Degree Program in Ecology, Colorado State University
Jan. 2012-18 Graduate Program Advisor for the Department of Ecosystem Science and Sustainability, Natural Resource Ecology Laboratory, Colorado State University.
Aug. 2010 Assistant Professor, Department of Ecosystem Science and Sustainability, Colorado State University.
July 2009 Research Scientist II, Natural Resource Ecology Laboratory, Colorado State University & U.S. Geological Survey, FORT Science Center, Fort Collins, Colorado.
Feb. 2007-Present Faculty Member, Graduate Degree Program in Ecology (GDPE), Colorado State University
Feb. 2007-11 Joint Faculty Member, Department of Fish, Wildlife, and Conservation Biology, Colorado State University
Oct. 2006 Research Scientist, Natural Resource Ecology Laboratory, Colorado State University & U.S. Geological Survey, FORT Science Center, Fort Collins, Colorado.
Education and Certifications
2005 - 2006 Post Doctoral Research Fellow, Natural Resource Ecology Laboratory, Colorado State University & U.S. Geological Survey, FORT Science Center, Fort Collins, CO.
2000 - 2005 Doctorate of Philosophy in Ecology, Department of Biological Sciences, University of Alberta, Edmonton, Alberta.
1998 - 2000 Master of Science in Biology, Department of Biology, University of Regina, Regina, Saskatchewan.
1991 - 1996 Bachelor of Science double major in Ecology and Zoology, Department of Biological Sciences, University of Calgary, Calgary, Alberta.
Science and Products
Wyoming Landscape Conservation Initiative: Inventory and Long-Term Monitoring
The Wyoming Landscape Conservation Initiative (WLCI)
Incorporating Genetic Data into Spatially-explicit Population Viability Models for Gunnison Sage-grouse
Hierarchical Sage-Grouse Population Assessment Tool: Building a Foundation for True Adaptive Management
Landscape Genetics of Sage Grouse
Conservation of Sagebrush Ecosystems and Wildlife
Field of Sagebrush Dreams: Planting and Restoring Functional Sagebrush in Burned Landscapes
Investigating Impacts of Oil and Gas Development on Greater Sage-Grouse Using a Bayesian State-Space Model
Multi-scale Statewide Wyoming Greater Sage-grouse Trends Determined by Population Viability Analysis
Modeling Seasonal Habitat Requirements and Population Viability for Greater Sage-grouse in Wyoming
Assessing lek attendance of male greater sage‐grouse using fine‐resolution GPS data: Implications for population monitoring of lek mating grouse
Evaluation of genetic change from translocation among Gunnison Sage-Grouse (Centrocercus minimus) populations
U.S. Geological Survey science for the Wyoming Landscape Conservation Initiative—2017 annual report
Erratum - Greater sage-grouse population trends across Wyoming.
U.S. Geological Survey science for the Wyoming Landscape Conservation Initiative—2016 annual report
A conservation paradox in the Great Basin—Altering sagebrush landscapes with fuel breaks to reduce habitat loss from wildfire
Greater sage-grouse science (2015–17)—Synthesis and potential management implications
Sage grouse
Multi-model comparison highlights consistency in predicted effect of warming on a semi-arid shrub
Greater sage-grouse population trends across Wyoming
Minimizing effects of methodological decisions on interpretation and prediction in species distribution studies: An example with background selection
Hierarchical population monitoring of greater sage-grouse (Centrocercus urophasianus) in Nevada and California—Identifying populations for management at the appropriate spatial scale
Science and Products
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Filter Total Items: 58
Wyoming Landscape Conservation Initiative: Inventory and Long-Term Monitoring
The Wyoming Landscape Conservation Initiative (WLCI) addresses effects of land-use and climate changes on Southwest Wyoming’s natural resources. In partnership with twelve Federal, State, and local natural resource agencies, and non-governmental organizations– FORT and ten other USGS centers are conducting dozens of integrated science projects to assess the status of Southwest Wyoming’s natural...The Wyoming Landscape Conservation Initiative (WLCI)
The Wyoming Landscape Conservation Initiative (WLCI) addresses effects of land-use and climate changes on Southwest Wyoming’s natural resources. In partnership with twelve Federal, State, and local natural resource agencies, and non-governmental organizations– FORT and ten other USGS centers are conducting dozens of integrated science projects to assess the status of Southwest Wyoming’s natural...Incorporating Genetic Data into Spatially-explicit Population Viability Models for Gunnison Sage-grouse
This goal of this study is to develop a spatially explicit habitat-population modeling framework to assess the viability of Gunnison Sage-grouse and each of the seven populations (Gunnison Basin and six satellite populations).Hierarchical Sage-Grouse Population Assessment Tool: Building a Foundation for True Adaptive Management
USGS scientists and colleagues have designed a hierarchical monitoring framework for greater sage-grouse in Nevada, Wyoming, and northeastern California that will provide land managers with a monitoring and detection system to identify sage-grouse breeding locations (known as leks), clusters of leks, and populations where intervention may be necessary to sustain populations and to evaluate...Landscape Genetics of Sage Grouse
Greater and Gunnison sage-grouse populations are species considered for listing under the Endangered Species Act of 1973. Loss and fragmentation of sagebrush habitats are among the primary causes of decline in these species. A fundamental need for species conservation is to identify and subsequently maintain a set of connected populations. Landscape genetics combines the fields of population...Conservation of Sagebrush Ecosystems and Wildlife
Sagebrush ecosystems are diverse habitats found throughout western North America that support a variety of flora and fauna. Home to unique wildlife such as Sage-grouse, Sage Thrashers, Brewer's Sparrows, Ferruginous Hawks, and pygmy rabbits, these ecosystems have undergone intense changes since the time when millions of bison roamed the plains. European settlement and intense agricultural...Field of Sagebrush Dreams: Planting and Restoring Functional Sagebrush in Burned Landscapes
Increased wildfire-induced loss of sagebrush in North American shrublands are outpacing natural recovery and leading to substantial habitat loss for sagebrush-obligate species like sage-grouse. The products and information developed for this project will help restoration practitioners, biologists, and land managers evaluate the efficacy of sagebrush restoration approaches as well as their ability...Investigating Impacts of Oil and Gas Development on Greater Sage-Grouse Using a Bayesian State-Space Model
USGS and university researchers analyzed changes in male sage-grouse lek counts in Wyoming from 1984 through 2008, measuring disturbance owing to oil and gas development.Multi-scale Statewide Wyoming Greater Sage-grouse Trends Determined by Population Viability Analysis
USGS scientists and partners investigated sage-grouse population trends in Wyoming and at multiple spatial scales.Modeling Seasonal Habitat Requirements and Population Viability for Greater Sage-grouse in Wyoming
USGS has developed Greater Sage-grouse habitat-selection models for the nesting, summer, late brood rearing, and winter life stages in Wyoming to assess habitat quality and responses change across large landscapes. - Data
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Filter Total Items: 120
Assessing lek attendance of male greater sage‐grouse using fine‐resolution GPS data: Implications for population monitoring of lek mating grouse
Counts of males displaying on breeding grounds are the primary management tool used to assess population trends in lekking grouse species. Despite the importance of male lek attendance (i.e., proportion of males on leks available for detection) influencing lek counts, patterns of within season and between season variability in attendance rates are not well understood. We used high‐frequency globalAuthorsGregory T. Wann, Peter S. Coates, Brian G. Prochazka, John P. Severson, Adrian P. Monroe, Cameron L. AldridgeEvaluation of genetic change from translocation among Gunnison Sage-Grouse (Centrocercus minimus) populations
Maintenance of genetic diversity is important for conserving species, especially those with fragmented habitats or ranges. In the absence of natural dispersal, translocation can be used to achieve this goal, although the success of translocation can be difficult to measure. Here we evaluate genetic change following translocation in Gunnison Sage-Grouse (Centrocercus minimus), a species reduced toAuthorsShawna J Zimmerman, Cameron L. Aldridge, Anthony D. Apa, Sara J. Oyler-McCanceU.S. Geological Survey science for the Wyoming Landscape Conservation Initiative—2017 annual report
The Wyoming Landscape Conservation Initiative (WLCI) was established in 2008 to address the scientific and conservation questions associated with land use changes because of energy development and other factors in southwest Wyoming. Over the past decade, partners from U.S. Geological Survey (USGS), State and Federal land management agencies, universities, and the public have collaborated to implemAuthorsLinda Zeigenfuss, Ellen Aikens, Cameron L. Aldridge, Patrick J. Anderson, Timothy J. Assal, Zachary H. Bowen, Anna D. Chalfoun, Geneva W. Chong, Cheryl A. Eddy-Miller, Stephen S. Germaine, Tabitha Graves, Collin G. Homer, Christopher Huber, Aaron N. Johnston, Matthew J. Kauffman, Daniel J. Manier, Ryan R. McShane, Kirk A. Miller, Adrian P. Monroe, Anna Ortega, Annika W. Walters, Teal B. WyckoffErratum - Greater sage-grouse population trends across Wyoming.
No abstract available.AuthorsDavid R. Edmunds, Cameron L. Aldridge, Michael O'Donnell, Adrian P. MonroeU.S. Geological Survey science for the Wyoming Landscape Conservation Initiative—2016 annual report
This is the ninth annual report highlighting U.S. Geological Survey (USGS) science and decision-support activities conducted for the Wyoming Landscape Conservation Initiative (WLCI). The activities address specific management needs identified by WLCI partner agencies. In fiscal year (FY) 2016, there were 26 active USGS WLCI science-based projects. Of these 26 projects, one project was new for FY20AuthorsZachary H. Bowen, Ellen Aikens, Cameron L. Aldridge, Patrick J. Anderson, Timothy J. Assal, Anna D. Chalfoun, Geneva W. Chong, Cheryl A. Eddy-Miller, Steven L. Garman, Steve Germaine, Collin G. Homer, Aaron N. Johnston, Matthew J. Kauffman, Daniel J. Manier, Cynthia P. Melcher, Kirk A. Miller, Annika W. Walters, Jerrod D. Wheeler, Daniel J. Wieferich, Anna B. Wilson, Teal B. Wyckoff, Linda ZeigenfussByEcosystems Mission Area, Water Resources Mission Area, Science Synthesis, Analysis and Research Program, Land Management Research Program, Science Analytics and Synthesis (SAS) Program, Species Management Research Program, Earth Resources Observation and Science (EROS) Center , Fort Collins Science Center, Geology, Geophysics, and Geochemistry Science Center, Northern Rocky Mountain Science Center, Wyoming-Montana Water Science CenterA conservation paradox in the Great Basin—Altering sagebrush landscapes with fuel breaks to reduce habitat loss from wildfire
Interactions between fire and nonnative, annual plant species (that is, “the grass/fire cycle”) represent one of the greatest threats to sagebrush (Artemisia spp.) ecosystems and associated wildlife, including the greater sage-grouse (Centrocercus urophasianus). In 2015, U.S. Department of the Interior called for a “science-based strategy to reduce the threat of large-scale rangeland fire to habitAuthorsDouglas J. Shinneman, Cameron L. Aldridge, Peter S. Coates, Matthew J. Germino, David S. Pilliod, Nicole M. VaillantGreater sage-grouse science (2015–17)—Synthesis and potential management implications
Executive SummaryThe greater sage-grouse (Centrocercus urophasianus; hereafter called “sage-grouse”), a species that requires sagebrush (Artemisia spp.), has experienced range-wide declines in its distribution and abundance. These declines have prompted substantial research and management investments to improve the understanding of sage-grouse and its habitats and reverse declines in distributionAuthorsSteven E. Hanser, Patricia A. Deibert, John C. Tull, Natasha B. Carr, Cameron L. Aldridge, Travis D. Bargsten, Thomas J. Christiansen, Peter S. Coates, Michele R. Crist, Kevin E. Doherty, Ethan A. Ellsworth, Lee J. Foster, Vicki A. Herren, Kevin H. Miller, Ann Moser, Robin M. Naeve, Karen L. Prentice, Thomas E. Remington, Mark A. Ricca, Douglas J. Shinneman, Richard L. Truex, Lief A. Wiechman, Dereck C. Wilson, Zachary H. BowenSage grouse
Sage grouse are a group of chicken-sized birds with a unique breeding behavior and dependence on sagebrush shrubs (genus Artemisia) for food and shelter throughout their life cycle. In the last century, human population expansion throughout western North America has reduced the amount of sagebrush and degraded and fragmented the remaining areas. Vanishing sagebrush has resulted in sage grouse (genAuthorsShawna Zimmerman, Jennifer M. Timmer, Cameron L. Aldridge, Sara J. Oyler-McCance, Clait E. Braun, Jessica R. YoungMulti-model comparison highlights consistency in predicted effect of warming on a semi-arid shrub
A number of modeling approaches have been developed to predict the impacts of climate change on species distributions, performance, and abundance. The stronger the agreement from models that represent different processes and are based on distinct and independent sources of information, the greater the confidence we can have in their predictions. Evaluating the level of confidence is particularly iAuthorsKatherine M. Renwick, Caroline Curtis, Andrew R. Kleinhesselink, Daniel R. Schlaepfer, Bethany A. Bradley, Cameron L. Aldridge, Benjamin Poulter, Peter B. AdlerGreater sage-grouse population trends across Wyoming
The scale at which analyses are performed can have an effect on model results and often one scale does not accurately describe the ecological phenomena of interest (e.g., population trends) for wide-ranging species: yet, most ecological studies are performed at a single, arbitrary scale. To best determine local and regional trends for greater sage-grouse (Centrocercus urophasianus) in Wyoming, USAAuthorsDavid R. Edmunds, Cameron L. Aldridge, Michael O'Donnell, Adrian P. MonroeMinimizing effects of methodological decisions on interpretation and prediction in species distribution studies: An example with background selection
Evaluating the conditions where a species can persist is an important question in ecology both to understand tolerances of organisms and to predict distributions across landscapes. Presence data combined with background or pseudo-absence locations are commonly used with species distribution modeling to develop these relationships. However, there is not a standard method to generate background or pAuthorsCatherine S. Jarnevich, Marian Talbert, Jeffrey T. Morisette, Cameron L. Aldridge, Cynthia Brown, Sunil Kumar, Daniel J. Manier, Colin Talbert, Tracy R. HolcombeHierarchical population monitoring of greater sage-grouse (Centrocercus urophasianus) in Nevada and California—Identifying populations for management at the appropriate spatial scale
Population ecologists have long recognized the importance of ecological scale in understanding processes that guide observed demographic patterns for wildlife species. However, directly incorporating spatial and temporal scale into monitoring strategies that detect whether trajectories are driven by local or regional factors is challenging and rarely implemented. Identifying the appropriate scaleAuthorsPeter S. Coates, Brian G. Prochazka, Mark A. Ricca, Gregory T. Wann, Cameron L. Aldridge, Steven E. Hanser, Kevin Doherty, Michael S. O'Donnell, David R. Edmunds, Shawn P. Espinosa - Software
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