Your search keyword '"Abelson, Eric S."' showing total 11 results

1. Big brains reduce extinction risk in Carnivora

Author

Abelson, Eric S.

Published

2019

2. Nearby night lighting, rather than sky glow, is associated with habitat selection by a top predator in human-dominated landscapes.

Author

Barrientos, Rafael, Vickers, Winston, Longcore, Travis, Abelson, Eric S., Dellinger, Justin, Waetjen, David P., Fandos, Guillermo, and Shilling, Fraser M.

Subjects

TOP predators, PUMAS, LUNAR phases, LIGHT pollution, THERMOLUMINESCENCE, DAYLIGHT, HABITAT selection, ECOSYSTEMS

Abstract

Artificial light at night (ALAN) is increasing in extent and intensity across the globe. It has been shown to interfere with animal sensory systems, orientation and distribution, with the potential to cause significant ecological impacts. We analysed the locations of 102 mountain lions (Puma concolor) in a light-polluted region in California. We modelled their distribution relative to environmental and human-disturbance variables, including upward radiance (nearby lights), zenith brightness (sky glow) and natural illumination from moonlight. We found that mountain lion probability of presence was highly related to upward radiance, that is, related to lights within approximately 500 m. Despite a general pattern of avoidance of locations with high upward radiance, there were large differences in degree of avoidance among individuals. The amount of light from artificial sky glow was not influential when included together with upward radiance in the models, and illumination from moonlight was not influential at all. Our results suggest that changes in visibility associated with lunar cycles and sky glow are less important for mountain lions in their selection of light landscapes than avoiding potential interactions with humans represented by the presence of nearby lights on the ground. This article is part of the theme issue 'Light pollution in complex ecological systems'. [ABSTRACT FROM AUTHOR]

Published

2023

3. Brain size is correlated with endangerment status in mammals

Author

Abelson, Eric S.

Published

2016

4. Vehicular traffic effects on elk and white-tailed deer behavior near wildlife underpasses.

Author

Nojoumi, Mehdi, Clevenger, Anthony P., Blumstein, Daniel T., and Abelson, Eric S.

Subjects

DEER behavior, CORRIDORS (Ecology), WHITE-tailed deer, ANIMAL behavior, RED deer, ELK

Abstract

Roads fragment animal populations, vehicles kill and injure animals, and traffic may affect animal behavior. Mitigation efforts (e.g., wildlife underpasses) are constructed to prevent fragmentation and reduce wildlife-vehicle collisions. However, little is known about traffic's proximal effects on wildlife behavior and use of mitigation measures. We quantified the time that elk (Cervus elaphus) and white-tailed deer (Odocoileus virginianus) allocated to foraging, vigilance, and flight behavior before and after vehicle passage. Both species increased vigilance and flight behaviors and reduced time spent foraging in response to vehicles. Both species were more likely to move through the underpass if they exhibited foraging behavior; we also found a marginally significant trend that animals were less likely to use the underpass after vigilance behavior. Knowledge that vehicle movement influences wildlife behavior underscores the importance of consideration given to road and crossing structure design. Additionally, findings of species-specific response to vehicle passage are important in understanding potential fitness consequences of anthropogenic disturbance. [ABSTRACT FROM AUTHOR]

Published

2022

5. Evaluating pathways to social and ecological landscape resilience.

Author

Abelson, Eric S., Reynolds, Keith M., White, Angela M., Long, Jonathan W., Maxwell, Charles, and Manley, Patricia N.

Subjects

*ECOLOGICAL resilience, *ENVIRONMENTAL quality, *FOREST biomass, *DROUGHTS, *FOREST resilience, *DROUGHT management, *RANGE management

Abstract

Rapid environmental changes challenge the resilience of wildlands. The western portion of the Lake Tahoe Basin in California is an important ecological and cultural hotspot that is at risk of degradation from current and future environmental pressures. Historical uses, fire suppression, and a changing climate have created forest landscape conditions at risk of drought stress, destructive fire, and loss of habitat diversity. We prospectively modeled forest landscape conditions for a period of 100 years to evaluate the efficacy of 5 unique management scenarios in achieving desired landscape conditions. Management scenarios ranged from no management other than fire suppression to applying treatments consistent with historical fire frequencies and extent (i.e., regular and broadscale biomass reduction). We developed a decision support tool to evaluate environmental and social outcomes within a single framework to provide a transparent set of costs and benefits. Results illuminated underlying mechanisms of forest resilience and provided actionable guidance to decision makers. Sixteen attributes were assessed in the model after assigning weights to each. We found that removing forest biomass across the landscape, particularly when accomplished using extensive fire-based removal techniques, led to highly favorable conditions for environmental quality and promoted overall landscape resilience. Environmental conditions resulting from extensive fire-based biomass removal also had nominal variation over time, in contrast with strategies that had less extensive and/or used physical removal techniques (e.g., mechanical thinning). Our analysis provides a transparent approach to assess large datasets with complex and interacting variables. Ultimately, we aim to provide insights into the complexities of maintaining optimal conditions and managing landscapes to promote ecosystem resilience in a changing world. [ABSTRACT FROM AUTHOR]

Published

2022

6. Management and Analysis of Camera Trap Data: Alternative Approaches (Response to Harris et al. 2010)

Author

Sundaresan, Siva R., Riginos, Corinna, and Abelson, Eric S.

Published

2011

7. The evolution of self-medication behaviour in mammals.

Author

Neco, Lucia C, Abelson, Eric S, Brown, Asia, Natterson-Horowitz, Barbara, and Blumstein, Daniel T

Subjects

*MAMMAL evolution, *BODY size, *COST of living, *EXTERNALITIES, *SIZE of brain

Abstract

Self-medication behaviour is the use of natural materials or chemical substances to manipulate behaviour or alter the body's response to parasites or pathogens. Self-medication can be preventive, performed before an individual becomes infected or diseased, and/or therapeutic, performed after an individual becomes infected or diseased. We summarized all available reports of self-medication in mammals and reconstructed its evolution. We found that reports of self-medication were restricted to eutherian mammals and evolved at least four times independently. Self-medication was most commonly reported in primates. Detailed analyses of primates suggest that self-medication is a life-history trait associated with body size, absolute brain size and longevity, but we found no support for the hypothesis that self-medication evolved to reduce the costs of social living. Large, longer-lived species might thus benefit uniquely from self-medication. [ABSTRACT FROM AUTHOR]

Published

2019

8. Canid vs. canid: insights into coyote-dog encounters from social media.

Author

BOYDSTON, ERIN E., ABELSON, ERIC S., KAZANJIAN, ARI, and BLUMSTEIN, DANIEL T.

Subjects

DOG behavior, SOCIAL media, COYOTE

Abstract

While the relationship between coyotes (Canis latrans) and house cats (Felis catus) may be characterized as one between predators and their prey, coyote interactions with domestic dogs (C. lupus familiaris) appear to be more varied and may include behaviors associated with canid sociality. While encounters between coyotes and dogs are difficult to observe, we capitalized on publicly available video recordings of coyote-dog encounters to observe canid behaviors and examined 35 video clips downloaded from YouTube during fall 2014. We identified coyote-dog interactions that were playful, agonistic, or predatory; those that we could not clearly categorize were labeled as other/undetermined. We found that both species were recorded directing play to the other species, which led to mutual play bouts. We observed a similar number of agonistic encounters, which included dogs biting coyotes and coyotes biting dogs. The main difference in agonistic behavior was that coyotes usually showed defensive aggression while dogs did not show defensive aggression. We also observed coyotes ambushing and bite-shaking small dogs in 3 video clips, from which the dogs escaped, but we did not see predatory behavior of dogs toward coyotes. Dog size may be related to types of interactions. No small dogs were involved in agonistic interactions, and only 1 small dog was observed playing with a coyote. From these videos, we conclude that the relationship between coyotes and dogs cannot be simply described as predator-prey; indeed, much of it appears to be social behavior divided between playful and agonistic. Future work that aims to explain the proximate correlates of play and aggression would provide more information for managers who wish to educate humans to reduce human-wildlife conflicts. [ABSTRACT FROM AUTHOR]

Published

2018

9. Ecology in the age of automation.

Author

Keitt, Timothy H. and Abelson, Eric S.

Subjects

*TECHNOLOGY, *NATURE, *CLIMATOLOGY

Abstract

The article presents the discussion on technology revolutionizing the study of organisms in the natural environment monitoring the distribution and abundance of species along with climate and other variables.

Published

2021

10. Strategic decision support for long-term conservation management planning.

Author

Abelson, Eric S., Reynolds, Keith M., Manley, Patricia, and Paplanus, Steven

Subjects

FOREST dynamics, FOREST management, ECOLOGICAL resilience, WATERSHEDS, DECISION making

Abstract

• Understanding forest response to perturbations over long time spans is important. • Designed a decision support tool (DST) to assess five modeled forests over 100 years. • The five modeled forests reflected management developed to explore ecosystem resilience. • DST design yielded a transparent framework to assess ecological variables/perspectives. • We found widescale biomass removal resulted in more favorable ecological outcomes. Forward thinking conservation-planning can benefit from modeling future landscapes that result from multiple alternative management scenarios. However, long-term landscape modeling and downstream analyses of modeling results can lead to massive amounts of data that are difficult to assemble, analyze, and to report findings in a way that is easily accessible to decision makers. In this study, we developed a decision support process to evaluate modeled forest conditions resulting from five management scenarios, across 100 years in California's Lake Tahoe basin; to this end we drew upon a large and complex hierarchical dataset intended to evaluate landscape resilience. Trajectories of landscape characteristics used to inform an analysis of landscape resilience were modeled with the spatially explicit LANDIS-II vegetation simulator. Downstream modeling outputs of additional landscape characteristics were derived from the LANDIS-II outputs (e.g., wildlife conditions, water quality, effects of fire). The later modeling processes resulted in the generation of massive data sets with high dimensionality of landscape characteristics at both high spatial and temporal resolution. Ultimately, our analysis distilled hundreds of data inputs into performance trajectories for the five modeled management scenarios over a 100-year time horizon. We then evaluated each management scenario based on inter-year variability, and absolute and relative performance. We found that management scenarios with a greater emphasis on proactive biomass reduction outperformed management approaches with minimal biomass reduction. These results, and the process that led to them, provided decision makers with insight into forest dynamics based on a rational, transparent, and repeatable decision support processes. [ABSTRACT FROM AUTHOR]

Published

2021

11. Simulating wildlife habitat dynamics over the next century to help inform best management strategies for biodiversity in the Lake Tahoe Basin, California.

Author

White, Angela M., Holland, Tim G., Abelson, Eric S., Kretchun, Alec, Maxwell, Charles J., and Scheller, Robert M.

Subjects

*WATERSHEDS, *FOREST management, *BIODIVERSITY, *FOREST density, *TREE mortality, *HABITATS

Abstract

Many forests of the western United States have undergone over one hundred years of anthropogenic impacts that have led to increased tree density, homogenization in forest structure, and accumulation of woody material, which combined with a changing climate pose threats to valued social and ecological features. In California, recent waves of tree mortality and unprecedented large and destructive fires have led to rising concerns about the impact of these disturbances on biodiversity and how forest management actions can mitigate negative impacts. To better understand the degree to which different management scenarios could mitigate the negative impacts of these disturbances on biodiversity, we used a spatially explicit modeling platform to model forest management impacts on habitat for terrestrial vertebrate species in the Lake Tahoe Basin of California and Nevada. Specifically, we modeled how 5 different management scenarios that differed in the type of fuel reduction treatment (e.g., fire and mechanical removal of vegetation) and extent of area treated influenced the amount, value, and distribution of reproductive habitat for the 159 species present in the study area. Our model results suggested that within the study area forest growth was predicted to out-pace disturbance leading to a higher percentage of late seral conditions; however, choice of management strategy impacted the composition and structure of the forested landscape leading to different trajectories for wildlife. In general, scenarios that allowed for more extensive use of fire led to a more equitable distribution of habitat types, whereas extensive thinning by hand and mechanical methods resulted in future forest structure that provided better outcomes in terms of reproductive habitat for wildlife. Our modeling results also suggested that low to moderate management strategies were not likely to change the current trajectory to more dense forests dominated by fewer species. [ABSTRACT FROM AUTHOR]

Published

2022