Your search keyword '"Buler, Jeffrey"' showing total 10 results

1. Artificial light at night is a top predictor of bird migration stopover density

Author

Horton, Kyle G., Buler, Jeffrey J., Anderson, Sharolyn J., Burt, Carolyn S., Collins, Amy C., Dokter, Adriaan M., Guo, Fengyi, Sheldon, Daniel, Tomaszewska, Monika Anna, and Henebry, Geoffrey M.

Published

2023

2. Seasonal patterns and protection status of stopover hotspots for migratory landbirds in the eastern United States

Author

Guo, Fengyi, Buler, Jeffrey J., Smolinsky, Jaclyn A., and Wilcove, David S.

Published

2024

3. Relating weather radar data to migrating waterfowl abundance in the Rainwater Basin of Nebraska.

Author

Liu, Boyan, Kemink, Kaylan, Sieges, Mason, Smolinsky, Jaclyn, Varner, Dana, and Buler, Jeffrey

Subjects

SURVEILLANCE radar, RAINWATER, WETLANDS, BIRD migration, REMOTE sensing, FIELD research, RADAR meteorology

Abstract

Waterfowl migrations are large‐scale events that involve millions of birds moving over broad geographic extents, which make them difficult to quantify and study. Historically, wildlife managers have relied mostly on field surveys, such as visual counts from the ground or air that sample at small spatial or temporal extents, or both. Combining field surveys with remote sensing data comprehensively collected over large spatial extents at high temporal frequency may improve the study of migrating waterfowl distributions. We tested the strength of the relationship between broad‐scale weather surveillance radar data and fine‐scale field surveys of waterfowl abundance at wetlands within the Rainwater Basin of Nebraska, USA, from 2017–2019. Radar reflectivity of waterfowl at the peak exodus of evening flights was positively correlated with diurnal waterfowl count data, although there was unexplained variation in the relationship. The association was also very similar across various time scales ranging from daily to monthly averages of waterfowl abundance. We suggest that human‐based ground surveys can calibrate and leverage more comprehensive remote sensing data to get a broad understanding of waterfowl distributions during migration. Several confounding factors, such as spatial displacement between radar and survey observation, individual variation in orientation and body size, and identification of avian species sampled by radar, remain on the path to improving radar‐based waterfowl estimates. [ABSTRACT FROM AUTHOR]

Published

2023

4. Autumn stopover hotspots and multiscale habitat associations of migratory landbirds in the eastern United States.

Author

Fengyi Guo, Buler, Jeffrey J., Smolinsky, Jaclyn A., and Wilcove, David S.

Subjects

*AUTUMN, *WEATHER radar networks, *BIRD conservation, *DECIDUOUS forests, *HABITAT conservation

Abstract

Halting the global decline of migratory birds requires a better understanding of migration ecology. Stopover sites are a crucial yet understudied aspect of bird conservation, mostly due to challenges associated with understanding broad-scale patterns of transient habitat use. Here, we use a national network of weather radar stations to identify stopover hotspots and assess multiscale habitat associations of migratory landbirds across the eastern United States during autumn migration. We mapped seasonal bird densities over 5 y (2015 to 2019) from 60 radar stations covering 63.2 million hectares. At a coarse scale, we found that landbirds migrate across a broad front with small differences in migrant density between radar domains. However, relatively more birds concentrate along the Mississippi River and Appalachian Mountains. At a finer scale, we identified radar pixels that consistently harbored high densities of migrants for all 5 y, which we classify as stopover hotspots. Hotspot probability increased with percent cover of all forest types and decreased with percent cover of pasture and cultivated crops. Moreover, we found strong concentrating effects of deciduous forest patches within deforested regions. We also found that the prairie biome in the Midwest (now mostly cropland) is likely a migration barrier, with large concentrations of migrants at the prairie--forest boundary after crossing the agricultural Midwest. Overall, the broad-front migration pattern highlights the importance of locally based conservation efforts to protect stopover habitats. Such efforts should target forests, especially deciduous forests in highly altered landscapes. These findings demonstrate the value of multiscale habitat assessments for the conservation of migratory landbirds. [ABSTRACT FROM AUTHOR]

Published

2023

5. Using weather radar to help minimize wind energy impacts on nocturnally migrating birds.

Author

Cohen, Emily B., Buler, Jeffrey J., Horton, Kyle G., Loss, Scott R., Cabrera‐Cruz, Sergio A., Smolinsky, Jaclyn A., and Marra, Peter P.

Subjects

*WIND power, *WEATHER radar networks, *ENERGY development, *RADAR meteorology, *SURVEILLANCE radar, *WINTER

Abstract

As wind energy rapidly expands worldwide, information to minimize impacts of this development on biodiversity is urgently needed. Here we demonstrate how data collected by weather radar networks can inform placement and operation of wind facilities to reduce collisions and minimize habitat‐related impacts on nocturnally migrating birds. We found over a third of nocturnal migrants flew through altitudes within the rotor‐swept zone surrounding the North American Great Lakes, a continentally important migration corridor. Migrating birds concentrated in terrestrial stopover habitats within 20‐km from shorelines, a distance well beyond the current guidelines for construction of new land‐based facilities, and their distributions varied seasonally and at local and regional scales, creating predictable opportunities to minimize impacts from wind energy development and operation. Networked radar data are available across the United States and other countries and broad application of this approach could provide information critical to bird‐friendly expansion of this globally important energy source. [ABSTRACT FROM AUTHOR]

Published

2022

6. Repurposing open‐source data from weather radars to reduce the costs of aerial waterbird surveys.

Author

Rogers, Rebecca M., Buler, Jeffrey, Clancy, Timothy, and Campbell, Hamish

Published

2022

7. Winds aloft over three water bodies influence spring stopover distributions of migrating birds along the Gulf of Mexico coast.

Author

Clipp, Hannah L., Buler, Jeffrey J., Smolinsky, Jaclyn A., Horton, Kyle G., Farnsworth, Andrew, and Cohen, Emily B.

Subjects

*MIGRATORY birds, *STAGING areas (Birds), *BIRD migration, *WINDS aloft

Abstract

Migrating birds contend with dynamic wind conditions that ultimately influence most aspects of their migration, from broad-scale movements to individual decisions about where to rest and refuel. We used weather surveillance radar data to measure spring stopover distributions of northward migrating birds along the northern Gulf of Mexico coast and found a strong influence of winds over nonadjacent water bodies, the Caribbean Sea and Atlantic Ocean, along with the contiguous Gulf of Mexico. Specifically, we quantified the relative influence of meridional (north-south) and zonal (west-east) wind components over the 3 water bodies on weekly spring stopover densities along western, central, and eastern regions of the northern Gulf of Mexico coast. Winds over the Caribbean Sea and Atlantic Ocean were just as, or more, influential than winds over the Gulf of Mexico, with the highest stopover densities in the central and eastern regions of the coast following the fastest winds from the east over the Caribbean Sea. In contrast, stopover density along the western region of the coast was most influenced by winds over the Gulf of Mexico, with the highest densities following winds from the south. Our results elucidate the important role of wind conditions over multiple water bodies on regionwide stopover distributions and complement tracking data showing Nearctic-Neotropical birds flying nonstop from South America to the northern Gulf of Mexico coast. Smaller-bodied birds may be particularly sensitive to prevailing wind conditions during nonstop flights over water, with probable orientation and energetic consequences that shape subsequent terrestrial stopover distributions. In the future, the changing climate is likely to alter wind conditions associated with migration, so birds that employ nonstop over-water flight strategies may face growing challenges. [ABSTRACT FROM AUTHOR]

Published

2021

8. Using the California Waterfowl Tracker to Assess Proximity of Waterfowl to Commercial Poultry in the Central Valley of California.

Author

Acosta, Sarai, Kelman, Todd, Feirer, Shane, Matchett, Elliott, Smolinsky, Jaclyn, Pitesky, Maurice, and Buler, Jeffrey

Subjects

WATERFOWL, BIOSECURITY, AVIAN influenza A virus, POULTRY, SPECIFIC gravity, POULTRY farms, REMOTE-sensing images

Abstract

Copyright of Avian Diseases is the property of American Association of Avian Pathologists, Inc. and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2021

9. Potential Effect of Low-Rise, Downcast Artificial Lights on Nocturnally Migrating Land Birds.

Author

Cabrera-Cruz, Sergio A, Larkin, Ronald P, Gimpel, Maren E, Gruber, James G, Zenzal, Theodore J, and Buler, Jeffrey J

Subjects

BIRD flight, CLOUDINESS, LIGHT emitting diodes, BIRD behavior, CITIES & towns, LIGHT sources, ELECTRON field emission, MONOCHROMATIC light

Abstract

Artificial light at night (ALAN) on tall or upward-pointed lighting installations affects the flight behavior of night-migrating birds. We hypothesized that common low-rise lights pointing downward also affect the movement of nocturnal migrants. We predicted that birds in flight will react close to low-rise lights, and be attracted and grounded near light sources, with a stronger effect on juveniles during their autumn migration. We conducted a controlled longitudinal experiment with light-emitting diode floodlights and considered nearby structures that turn on lights at night. We analyzed 1501 high-resolution 3D nocturnal flight paths of free-flying migrants and diurnally captured 758–2009 birds around experimental lights during spring and autumn 2016, and spring 2017. We identified change points along flight paths where birds turned horizontally or vertically, and we considered these indicative of reactions. Flight paths with and without reactions were generally closer to our experimental site in spring than in autumn when the lights were on. Reactions were up to 40% more likely to occur in autumn than in spring depending on the threshold magnitude of turning angle. Reactions in spring were up to ∼60% more likely to occur at ∼35 m from the lights than at >1.5 km. In autumn, some vertical reactions were ∼40% more likely to occur at ∼50 m from the lights than at >2.2 km. Interactions between distance to lights and visibility or cloud cover were consistent with known effects of ALAN on nocturnal migrants. Under poor visibility, reactions were up to 50% more likely to occur farthest from structures in spring, but up to 60% more likely to occur closest to lights in autumn. Thus, the effects of ALAN on night-migrating land birds are not limited to bright lights pointing upward or lights on tall structures in urban areas. Diurnal capture rates of birds were not different when lights were on or off for either season. To our knowledge, this is the first study to show that low-rise lights pointing downward affect night-migrating birds. Although the interpreted reactions constitute subtle modifications in the linearity of flight paths, we discuss future work that could verify whether the protection of nocturnal migrants with lights-out programs would have greater impact if implemented beyond urban areas and include management of low-rise lights. [ABSTRACT FROM AUTHOR]

Published

2021

10. Autumn stopover hotspots and multiscale habitat associations of migratory landbirds in the eastern United States.

Author

Guo F, Buler JJ, Smolinsky JA, and Wilcove DS

Subjects

Animals, United States, Seasons, Forests, Birds, Mississippi, Animal Migration, Ecosystem

Abstract

Halting the global decline of migratory birds requires a better understanding of migration ecology. Stopover sites are a crucial yet understudied aspect of bird conservation, mostly due to challenges associated with understanding broad-scale patterns of transient habitat use. Here, we use a national network of weather radar stations to identify stopover hotspots and assess multiscale habitat associations of migratory landbirds across the eastern United States during autumn migration. We mapped seasonal bird densities over 5 y (2015 to 2019) from 60 radar stations covering 63.2 million hectares. At a coarse scale, we found that landbirds migrate across a broad front with small differences in migrant density between radar domains. However, relatively more birds concentrate along the Mississippi River and Appalachian Mountains. At a finer scale, we identified radar pixels that consistently harbored high densities of migrants for all 5 y, which we classify as stopover hotspots. Hotspot probability increased with percent cover of all forest types and decreased with percent cover of pasture and cultivated crops. Moreover, we found strong concentrating effects of deciduous forest patches within deforested regions. We also found that the prairie biome in the Midwest (now mostly cropland) is likely a migration barrier, with large concentrations of migrants at the prairie-forest boundary after crossing the agricultural Midwest. Overall, the broad-front migration pattern highlights the importance of locally based conservation efforts to protect stopover habitats. Such efforts should target forests, especially deciduous forests in highly altered landscapes. These findings demonstrate the value of multiscale habitat assessments for the conservation of migratory landbirds.

Published

2023