The influence of mitigation on sage-grouse habitat selection within an energy development field

The influence of mitigation on sage-grouse habitat selection within an energy development field

Growing global energy demands ensure the continued growth of energy development. Energy development in wildlife areas can significantly impact wildlife populations. Efforts to mitigate development impacts to wildlife are on-going, but the effectiveness of such efforts is seldom monitored or assessed...

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Bibliographic Details
Published in:PloS one 2015-04, Vol.10 (4), p.e0121603-e0121603
Main Authors: Fedy, Bradley C, Kirol, Christopher P, Sutphin, Andrew L, Maechtle, Thomas L
Format: Article
Language:eng
Subjects:
Animals
Animals, Wild - physiology
Artemisia tridentata
Avoidance
Behavior
Birds
Centrocercus urophasianus
Conservation of Natural Resources - methods
Conservation of Natural Resources - statistics & numerical data
Ecosystem
Electric power plant construction
Electric Power Supplies
Energy
Environmental aspects
Female
Fitness
Galliformes - physiology
Habitat improvement
Habitat selection
Habitat utilization
Humans
Landscape
Logistic Models
Male
Methods
Mitigation
Models, Statistical
Nesting
Nesting Behavior - physiology
Nests
Population Density
Regression analysis
Spatial distribution
Statistical analysis
Tetraoninae
Wells
Wildlife habitats
Wildlife management
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Summary:Growing global energy demands ensure the continued growth of energy development. Energy development in wildlife areas can significantly impact wildlife populations. Efforts to mitigate development impacts to wildlife are on-going, but the effectiveness of such efforts is seldom monitored or assessed. Greater sage-grouse (Centrocercus urophasianus) are sensitive to energy development and likely serve as an effective umbrella species for other sagebrush-steppe obligate wildlife. We assessed the response of birds within an energy development area before and after the implementation of mitigation action. Additionally, we quantified changes in habitat distribution and abundance in pre- and post-mitigation landscapes. Sage-grouse avoidance of energy development at large spatial scales is well documented. We limited our research to directly within an energy development field in order to assess the influence of mitigation in close proximity to energy infrastructure. We used nest-location data (n = 488) within an energy development field to develop habitat selection models using logistic regression on data from 4 years of research prior to mitigation and for 4 years following the implementation of extensive mitigation efforts (e.g., decreased activity, buried powerlines). The post-mitigation habitat selection models indicated less avoidance of wells (well density β = 0.18 ± 0.08) than the pre-mitigation models (well density β = -0.09 ± 0.11). However, birds still avoided areas of high well density and nests were not found in areas with greater than 4 wells per km2 and the majority of nests (63%) were located in areas with ≤ 1 well per km2. Several other model coefficients differed between the two time periods and indicated stronger selection for sagebrush (pre-mitigation β = 0.30 ± 0.09; post-mitigation β = 0.82 ± 0.08) and less avoidance of rugged terrain (pre-mitigation β = -0.35 ± 0.12; post-mitigation β = -0.05 ± 0.09). Mitigation efforts implemented may be responsible for the measurable improvement in sage-grouse nesting habitats within the development area. However, we cannot reject alternative hypotheses concerning the influence of population density and intraspecific competition. Additionally, we were unable to assess the actual fitness consequences of mitigation or the source-sink dynamics of the habitats. We compared the pre-mitigation and post-mitigation models predicted as maps with habitats ranked from low to high relative probability of use (equal-are
ISSN:1932-6203
1932-6203