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3. Drivers of fatal bird collisions in an urban center

Author

Van Doren, Benjamin M., Willard, David E., Hennen, Mary, Horton, Kyle G., Stuber, Erica F., Sheldon, Daniel, Sivakumar, Ashwin H., Wang, Julia, Farnsworth, Andrew, and Winger, Benjamin M.

Published
2021

4. Chasing and surfing seasonal waves: Avian migration through the US tracks land surface phenology in fall, but not spring.

Author

Adams, Carrie Ann, Tomaszewska, Monika A., Henebry, Geoffrey M., and Horton, Kyle G.

Subjects
BIRD migration, SPRING, PHENOLOGY, SEASONS, PLANT phenology, VEGETATION greenness
Abstract

Climate change is altering the timing of seasonal events for many taxa.There is limited understanding of how northward/southward songbird migration follows or is limited by the latitudinal progression of seasonal transitions. Consistent environmental conditions that migrating birds encounter across latitudes likely represent or correlate with important resources or limiting factors for migration.We tested whether migratory passage—observed via radar—consistently tracked land surface variables and phenophases across latitudes in the US Central Flyway in both spring and fall.The daily temperatures, precipitation and vegetation greenness occurring on 10%, 50% and 90% cumulative passage dates changed substantially with latitude, indicating that most migrants experienced rapidly changing conditions as they headed north or south. Temperature did not limit the progression of migration in either season.Peak spring migration in the southern US occurred nearly 40 days after the spring green wave, the northward progression of vegetation growth, but nearly caught up to green‐up at 48° N. Spring migration phenology may have evolved to prioritize earlier arrival for breeding.Across all latitudes, peak fall migration coincided with the same land surface phenophase, an interval of 26 days prior to dormancy onset. Migrants may rely on phenological events in vegetation during fall stopovers.Considering that (a) migratory passage tracked fall land surface phenology across latitudes at a continental scale, (b) previous studies at local scales have demonstrated the importance of fruit during fall migratory stopover and (c) fruiting phenology in North America is occurring later over time while fall migration is advancing, the potential for mismatch between fall fruiting and bird migration phenology urgently needs further investigation. [ABSTRACT FROM AUTHOR]

Published
2024
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9. To mitigate bird collisions, enforce the Migratory Bird Treaty Act.

Author

Farnsworth, Andrew, Horton, Kyle G., and Marra, Peter P.

Subjects
*THUNDERSTORMS, *PUBLIC spaces, MIGRATORY Bird Treaty Act (U.S. : 1918)
Abstract

The article discusses the need for stronger enforcement of the Migratory Bird Treaty Act (MBTA) to protect birds from collisions with buildings. It highlights the significant number of bird deaths caused by these collisions and emphasizes the importance of bird-safe glass and building designs, as well as methods to reduce light pollution. The article mentions the Federal Bird Safe Buildings Act, which proposes requirements for bird-safe building materials and design features, but notes that it has yet to pass. The article concludes by suggesting that laws and enforcement are necessary to ensure the adoption of bird-safe solutions and reduce bird mortality. [Extracted from the article]

Published
2024
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14. Biomass burning in the Neotropics is exposing migrating birds to elevated fine particulate matter concentrations.

Author

La Sorte, Frank A., Zuckerberg, Benjamin, Lepczyk, Christopher A., Aronson, Myla F. J., and Horton, Kyle G.

Subjects
BIOMASS burning, PARTICULATE matter, LIFE cycles (Biology), POLLUTION, SPRING, WINTER, BIRD populations
Abstract

Aim: A unique risk faced by nocturnally migrating birds is the disorienting influence of artificial light at night (ALAN). ALAN originates from anthropogenic activities that can generate other forms of environmental pollution, including the emission of fine particulate matter (PM2.5). PM2.5 concentrations can display strong seasonal variation whose origin can be natural or anthropogenic. How this variation affects seasonal associations with ALAN and PM2.5 for nocturnally migrating bird populations has not been explored. Location: Western Hemisphere. Time Period: 2021 Major Taxa Studied: Nocturnally migrating passerine (NMP) bird species. Methods: We combined monthly estimates of PM2.5 and ALAN with weekly estimates of relative abundance for 164 NMP species derived using observations from eBird. We identified groups of species with similar associations with monthly PM2.5. We summarized their shared environmental, geographical, and ecological attributes. Results: PM2.5 was lowest in North America, especially at higher latitudes during the boreal winter. PM2.5 was highest in the Amazon Basin, especially during the dry season (August–October). ALAN was highest within eastern North America, especially during the boreal winter. For NMP species, PM2.5 associations reached their lowest levels during the breeding season (<10 μg/m3) and highest levels during the nonbreeding season, especially for long‐distance migrants that winter in Central and South America (~20 μg/m3). Species that migrate through Central America in the spring encountered similarly high PM2.5 concentrations. ALAN associations reached their highest levels for species that migrate (~12 nW/cm2/sr) or spend the nonbreeding season (~15 nW/cm2/sr) in eastern North America. Main Conclusions: We did not find evidence that the disorienting influence of ALAN enhances PM2.5 exposure during stopover in the spring and autumn for NMP species. Rather, our findings suggest biomass burning in the Neotropics is exposing NMP species to consistently elevated PM2.5 concentrations for an extended period of their annual life cycles. [ABSTRACT FROM AUTHOR]

Published
2023
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15. Citizen science to address the global issue of bird–window collisions.

Author

Loss, Scott R, Li, Binbin V, Horn, Lisa C, Mesure, Michael R, Zhu, Lei, Brys, Timothy G, Dokter, Adriaan M, Elmore, Jared A, Gibbons, Richard E, Homayoun, Tania Z, Horton, Kyle G, Inglet, Patsy, Jones, Benjamin J, Keys, Taylor, Lao, Sirena, Loss, Sara S, Parkins, Kaitlyn L, Prestridge, Heather L, Riggs, Georgia J, and Riding, Corey S

Subjects
CITIZEN science, BIRD mortality, NONGOVERNMENTAL organizations, GOVERNMENT agencies, AWARENESS
Abstract

Bird–window collisions (BWCs) are a major threat to avian populations, annually causing up to one billion bird deaths in the US alone and untold numbers of fatalities worldwide. Until recently, there has been limited institutional and governmental recognition of this issue and few coordinated, national‐level efforts to address it. To fill this need, citizen‐science campaigns have stepped in to generate scientific information about BWCs, raise public awareness, and advocate for policy and actions to reduce collisions. We review the BWC issue and showcase how citizen‐science programs in multiple countries have achieved these outcomes. Additional citizen‐driven successes in addressing BWCs are possible if key constraints are overcome, including funding limitations and challenges of proactively engaging stakeholders who can reduce BWCs at scale. Addressing this global conservation issue will also require building upon the recent increase in attention to BWCs by government agencies, nongovernmental organizations, commercial entities, and professional scientists. [ABSTRACT FROM AUTHOR]

Published
2023
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16. Space weather disrupts nocturnal bird migration.

Author

Gulson-Castillo, Eric R., Van Doren, Benjamin M., Bui, Michelle X., Horton, Kyle G., Jing Li, Moldwin, Mark B., Shedden, Kerby, Welling, Daniel T., and Winger, Benjamin M.

Subjects
BIRD migration, SPACE environment, NOCTURNAL birds, ANIMAL migration, GEOMAGNETISM
Abstract

Space weather, including solar storms, can impact Earth by disturbing the geomagnetic field. Despite the known dependence of birds and other animals on geomagnetic cues for successful seasonal migrations, the potential effects of space weather on organisms that use Earth's magnetic field for navigation have received little study. We tested whether space weather geomagnetic disturbances are associated with disruptions to bird migration at a macroecological scale. We leveraged long-term radar data to characterize the nightly migration dynamics of the nocturnally migrating North American avifauna over 22 y. We then used concurrent magnetometer data to develop a local magnetic disturbance index associated with each radar station (ΔBmax), facilitating spatiotemporally explicit analyses of the relationship between migration and geomagnetic disturbance. After controlling for effects of atmospheric weather and spatiotemporal patterns, we found a 9 to 17% decrease in migration intensity in both spring and fall during severe space weather events. During fall migration, we also found evidence for decreases in effort flying against the wind, which may represent a depression of active navigation such that birds drift more with the wind during geomagnetic disturbances. Effort flying against the wind in the fall was most reduced under both overcast conditions and high geomagnetic disturbance, suggesting that a combination of obscured celestial cues and magnetic disturbance may disrupt navigation. Collectively, our results provide evidence for community-wide avifaunal responses to geomagnetic disturbances driven by space weather during nocturnal migration. [ABSTRACT FROM AUTHOR]

Published
2023
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18. Inbound arrivals: using weather surveillance radar to quantify the diurnal timing of spring trans‐Gulf bird migration.

Author

Abbott, Annika L., Deng, Yuting, Badwey, Katie, Farnsworth, Andrew, and Horton, Kyle G.

Subjects
BIRD migration, SURVEILLANCE radar, RADAR meteorology, SPRING, MIGRATORY birds, WINTER
Abstract

More than two billion birds migrate through the Gulf of Mexico each spring en route to breeding grounds in the USA and Canada. This region has a long history of complex natural and anthropogenic environments as the northern Gulf coast provides the first possible stopover habitats for migrants making nonstop trans‐Gulf crossings during spring migration. However, intense anthropogenic activity in the region, which is expanding rapidly at present, makes migrants vulnerable to a multitude of obstacles and increasingly fragments and alters these habitats. Understanding the timing of migrants' overwater arrivals has biological value for expanding our understanding of migration ecology relative to decision‐making for nonstop flights, and is imperative for advancing conservation of this critical region through the identification of key times in which to direct conservation actions (e.g. temporary halting of wind turbines, reduction of light pollution). We explored 10 years of weather surveillance radar data from five sites along the northern Gulf of Mexico coast to quantify the daily timing and intensity of arriving trans‐Gulf migrants. On a daily scale, we found that migrant intensity peaked an average of nine hours after local sunrise, occurring earliest at easternmost sites. On a seasonal level, the greatest number of arrivals occurred between late April and early May, with peak intensity occurring latest at westernmost sites. Overall intensity of migration across all 10 years of data was greatest at the westernmost sites and decreased moving farther to the east. These findings emphasize the differential spatial and temporal patterns of use of the Gulf of Mexico region by migrating birds, information that is essential for improving our understanding of the ecology of trans‐Gulf migration and for supporting data‐driven approaches to conservation actions for the migratory birds passing through this critical region. [ABSTRACT FROM AUTHOR]

Published
2023
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19. Long‐term analysis of persistence and size of swallow and martin roosts in the US Great Lakes.

Author

Belotti, Maria Carolina T. D., Deng, Yuting, Zhao, Wenlong, Simons, Victoria F., Cheng, Zezhou, Perez, Gustavo, Tielens, Elske, Maji, Subhransu, Sheldon, Daniel, Kelly, Jeffrey F., Horton, Kyle G., Lecours, Vincent, and Van Den Broeke, Matthew

Subjects
ROOSTING, SURVEILLANCE radar, DEGLUTITION, RADAR meteorology, LAKES, MACHINE learning
Abstract

In this study, we combined a machine learning pipeline and human supervision to identify and label swallow and martin roost locations on data captured from 2000 to 2020 by 12 Weather Surveillance Radars in the Great Lakes region of the US. We employed radar theory to extract the number of birds in each roost detected by our technique. With these data, we set out to investigate whether roosts formed consistently in the same geographic area over two decades and whether consistency was also predictive of roost size. We used a clustering algorithm to group individual roost locations into 104 high‐density regions and extracted the number of years when each of these regions was used by birds to roost. In addition, we calculated the overall population size and analyzed the daily roost size distributions. Our results support the hypothesis that more persistent roosts are also gathering more birds, but we found that on average, most individuals congregate in roosts of smaller size. Given the concentrations and consistency of roosting of swallows and martins in specific areas throughout the Great Lakes, future changes in these patterns should be monitored because they may have important ecosystem and conservation implications. [ABSTRACT FROM AUTHOR]

Published
2023
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22. Can ecological forecasting lead to convergence on sustainable lighting policies?

Author

Burt, Carolyn S., Kelly, Jeffrey F., Fox, Andrew S., Jenkins‐Smith, Hank C., Leon‐Corwin, Maggie, Khalighifar, Ali, Trankina, Grace E., Silva, Carol L., and Horton, Kyle G.

Subjects
ECOLOGICAL forecasting, BIOTIC communities, PUBLIC opinion, COMMUNITY involvement, ECOLOGICAL modernization
Abstract

The overuse and expansion of artificial light at night (ALAN) has emerged from complex social, economic, and political factors, making it a societal problem that negatively impacts wildlife and people. We propose that a convergence research approach combining ecological forecasting with community engagement and public policy is needed to address this diverse societal problem. To begin this convergence research approach, we hosted a workshop to strengthen connections among key biodiversity‐oriented ALAN stakeholders and to better understand how stakeholder groups function across the United States through facilitated discussions. We have prioritized the input of stakeholders early in our research design by including them in the formulation of a national survey on public perceptions surrounding ALAN and received their input on existing ecological forecasting tools to improve those research products for their future use. [ABSTRACT FROM AUTHOR]

Published
2023
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26. Six decades of North American bird banding records reveal plasticity in migration phenology.

Author

Horton, Kyle G., Morris, Sara R., Van Doren, Benjamin M., and Covino, Kristen M.

Subjects
*BIRD migration, *BIRD banding, *WOOD warblers, *SPRING, *PLANT phenology, *PHENOLOGY, *CLIMATE change, *AUTUMN
Abstract

The timing of avian migration has evolved to exploit critical seasonal resources, yet plasticity within phenological responses may allow adjustments to interannual resource phenology. The diversity of migratory species and changes in underlying resources in response to climate change make it challenging to generalize these relationships.We use bird banding records during spring and fall migration from across North America to examine macroscale phenological responses to interannual fluctuations in temperature and long‐term annual trends in phenology.In total, we examine 19 species of North American wood warblers (family Parulidae), summarizing migration timing from 2,826,588 banded birds from 1961 to 2018 across 46 sites during spring and 124 sites during fall.During spring, warmer spring temperatures at banding locations translated to earlier median passage dates for 16 of 19 species, with an average 0.65‐day advancement in median passage for every 1°C increase in temperature, ranging from 0.25 to 1.26 days °C−1. During the fall, relationships were considerably weaker, with only 3 of 19 species showing a relationship with temperature. In those three cases, later departure dates were associated with warmer fall periods. Projecting these trends forward under climate scenarios of temperature change, we forecast continued spring advancements under shared socioeconomic pathways from 2041 to 2060 and 2081 to 2100 and more muted and variable shifts for fall.These results demonstrate the capacity of long‐distance migrants to respond to interannual fluctuations in temperatures, at least during the spring, and showcase the potential of North American bird banding data understanding phenological trends across a wide diversity of avian species. [ABSTRACT FROM AUTHOR]

Published
2023
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27. Quantifying long‐term phenological patterns of aerial insectivores roosting in the Great Lakes region using weather surveillance radar.

Author

Deng, Yuting, Belotti, Maria Carolina T. D., Zhao, Wenlong, Cheng, Zezhou, Perez, Gustavo, Tielens, Elske, Simons, Victoria F., Sheldon, Daniel R., Maji, Subhransu, Kelly, Jeffrey F., and Horton, Kyle G.

Subjects
SURVEILLANCE radar, RADAR meteorology, PLANT phenology, WEATHER radar networks, ROOSTING, MACHINE learning
Abstract

Organisms have been shifting their timing of life history events (phenology) in response to changes in the emergence of resources induced by climate change. Yet understanding these patterns at large scales and across long time series is often challenging. Here we used the US weather surveillance radar network to collect data on the timing of communal swallow and martin roosts and evaluate the scale of phenological shifts and its potential association with temperature. The discrete morning departures of these aggregated aerial insectivores from ground‐based roosting locations are detected by radars around sunrise. For the first time, we applied a machine learning algorithm to automatically detect and track these large‐scale behaviors. We used 21 years of data from 12 weather surveillance radar stations in the Great Lakes region to quantify the phenology in roosting behavior of aerial insectivores at three spatial levels: local roost cluster, radar station, and across the Great Lakes region. We show that their peak roosting activity timing has advanced by 2.26 days per decade at the regional scale. Similar signals of advancement were found at the station scale, but not at the local roost cluster scale. Air temperature trends in the Great Lakes region during the active roosting period were predictive of later stages of roosting phenology trends (75% and 90% passage dates). Our study represents one of the longest‐term broad‐scale phenology examinations of avian aerial insectivore species responding to environmental change and provides a stepping stone for examining potential phenological mismatches across trophic levels at broad spatial scales. [ABSTRACT FROM AUTHOR]

Published
2023
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28. Stopover strategies drive potential adaptability under changing environments.

Author

Horton, Kyle G. and Yuting Deng

Subjects
*MIGRATION flyways, *BIRD migration, *ANIMAL migration, *MIGRATORY animals, *MIGRATORY birds
Abstract

The article discusses the importance of stopover locations for migratory birds and the need for conservation efforts to protect these habitats. It focuses on the East Asian-Australasian Flyway (EAAF), which is one of the most threatened migratory bird flyways in the world. The Yellow Sea and Bohai Gulf region, located along the EAAF, are crucial stopover sites for many shorebird species, but they are experiencing habitat loss and degradation. The article emphasizes the need to understand and protect these stopover locations to ensure the survival of migratory bird populations. [Extracted from the article]

Published
2024
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29. The correlation between eBird community science and weather surveillance radar‐based estimates of migration phenology.

Author

Haas, Elaina K., La Sorte, Frank A., McCaslin, Hanna M., Belotti, Maria C. T. D., and Horton, Kyle G.

Subjects
PHENOLOGY, MIGRATION flyways, COMMUNITIES, RADAR meteorology, BIRD migration, PLANT phenology, BIRD populations
Abstract

Aim: Measuring avian migration can prove challenging given the spatial scope and the diversity of species involved. No one monitoring technique provides all the pertinent measures needed to capture this macroscale phenomenon – emphasizing the need for data integration. Migration phenology is a key metric characterizing large‐scale migration dynamics and has been successfully quantified using weather surveillance radar (WSR) data and community science observations. Separately, both platforms have their limitations and measure different aspects of bird migration. We sought to make a formal comparison of the migration phenology estimates derived from WSR and eBird data – of which we predict a positive correlation. Location: Contiguous United States. Time period: 2002–2018. Major taxa studied: Migratory birds. Methods: We estimated spring and autumn migration phenology at 143 WSR stations aggregated over a 17‐year period (2002–2018), which we contrast with eBird‐based estimates of spring and autumn migration phenology for 293 nocturnally migrating bird species at the 143 WSR stations. We compared phenology metrics derived from all species and WSR stations combined, for species in three taxonomic orders (Anseriformes, Charadriiformes and Passeriformes), and for WSR stations in three North American migration flyways (western, central and eastern). Results: We found positive correlations between WSR and eBird‐based estimates of migration phenology and differences in the strength of correlations among taxonomic orders and migration flyways. The correlations were stronger during spring migration, for Passeriformes, and generally for WSR stations in the eastern flyway. Autumn migration showed weaker correlation, and in Anseriformes correlations were weakest overall. Lastly, eBird‐based estimates slightly preceded those derived from WSR in the spring, but trailed WSR in the autumn, suggesting that the two data sources measure different components of migration phenology. Main conclusions We highlight the complementarity of these two approaches, but also reveal strong taxonomic and geographic differences in the relationships between the platforms. [ABSTRACT FROM AUTHOR]

Published
2022
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30. 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
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31. Assessing the combined threats of artificial light at night and air pollution for the world's nocturnally migrating birds.

Author

La Sorte, Frank A., Aronson, Myla F. J., Lepczyk, Christopher A., Horton, Kyle G., and Sheard, Catherine

Subjects
MIGRATION flyways, AIR pollution, BIRD populations, PARTICULATE matter, MATING grounds, HAZARDS
Abstract

Aim: Two important environmental hazards for nocturnally migrating birds are artificial light at night (ALAN) and air pollution, with ambient fine particulate matter (PM2.5) considered to be especially harmful. Nocturnally migrating birds are attracted to ALAN during seasonal migration, which could increase exposure to PM2.5. Here, we examine PM2.5 concentrations and PM2.5 trends and the spatial correlation between ALAN and PM2.5 within the geographical ranges of the world's nocturnally migrating birds. Location: Global. Time period: 1998–2018. Major taxa studied: Nocturnally migrating birds. Methods: We intersected a global database of annual mean PM2.5 concentrations over a 21‐year period (1998–2018) with the geographical ranges (breeding, non‐breeding and regions of passage) of 225 nocturnally migrating bird species in three migration flyways (Americas, n = 143; Africa–Europe, n = 36; and East Asia–Australia, n = 46). For each species, we estimated PM2.5 concentrations and trends and measured the correlation between ALAN and PM2.5, which we summarized by season and flyway. Results: Correlations between ALAN and PM2.5 were significantly positive across all seasons and flyways. The East Asia–Australia flyway had the strongest ALAN–PM2.5 correlations within regions of passage, the highest PM2.5 concentrations across all three seasons and the strongest positive PM2.5 trends on the non‐breeding grounds and within regions of passage. The Americas flyway had the strongest negative air pollution trends on the non‐breeding grounds and within regions of passage. The breeding grounds had similarly negative air pollution trends within the three flyways. Main conclusions: The combined threats of ALAN and air pollution are greatest and likely to be increasing within the East Asia–Australia flyway and lowest and likely to be decreasing within the Americas and Africa–Europe flyways. Reversing PM2.5 trends in the East Asia–Australia flyway and maintaining negative PM2.5 trends in the Americas and Africa–Europe flyways while reducing ALAN levels would likely be beneficial for the nocturnally migrating bird populations in each region. [ABSTRACT FROM AUTHOR]

Published
2022
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32. Seasonal associations with light pollution trends for nocturnally migrating bird populations.

Author

La Sorte, Frank A., Horton, Kyle G., Johnston, Alison, Fink, Daniel, and Auer, Tom

Subjects
BIRD populations, LIGHT pollution, NUMBERS of species, SCIENCE databases, PASSERIFORMES
Abstract

Artificial light at night (ALAN) is adversely affecting natural systems worldwide, including the disorienting influence of ALAN on nocturnally migrating birds. Understanding how ALAN trends are developing across species' seasonal distributions will inform mitigation efforts, such as Lights Out programs. Here, we intersect ALAN annual trend estimates (1992–2013) with weekly estimates of relative abundance for 42 nocturnally migrating passerine bird species that breed in North America using observations from the eBird community science database for the combined period 2005–2020. We use a cluster analysis to identify species with similar weekly associations with ALAN trends. Our results identified three prominent clusters. Two contained species that occurred in northeastern and western North America during the breeding season. These species were associated with moderate ALAN levels and weak negative ALAN trends during the breeding season, and low ALAN levels and strong positive ALAN trends during the nonbreeding season. The difference between the breeding and nonbreeding seasons was lower for species that occurred in northern South America and greater for species that occurred in Central America during the nonbreeding season. For species that occurred in South America during the nonbreeding season, positive ALAN trends increased in strength as species migrated through Central America, especially in the spring. The third cluster contained species whose associations with positive ALAN trends remained high across the annual cycle, peaking during migration, especially in the spring. These species occurred in southeastern North America during the breeding season where they were associated with high ALAN levels, and in northern South America during the nonbreeding season where they were associated with low ALAN levels. Our findings suggest reversing ALAN trends in Central America during migration, especially in the spring, would benefit the most individuals of the greatest number of species. Reversing ALAN trends in southeastern North America during the breeding season and Central America during the nonbreeding season would generate the greatest benefits outside of migration. [ABSTRACT FROM AUTHOR]

Published
2022
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33. Continental Patterns of Bird Migration Linked to Climate Variability.

Author

Dezfuli, Amin, Horton, Kyle G., Zuckerberg, Benjamin, Schubert, Siegfried D., and Bosilovich, Michael G.

Subjects
*BIRD migration, *ROSSBY waves, *PLANT phenology, *ATMOSPHERIC waves, *PHENOLOGY
Abstract

For ∼100 years, the continental patterns of avian migration in North America have been described in the context of three or four primary flyways. This spatial compartmentalization often fails to adequately reflect a critical characterization of migration—phenology. This shortcoming has been partly due to the lack of reliable continental-scale data, a gap filled by our current study. Here, we leveraged unique radar-based data quantifying migration phenology and used an objective regionalization approach to introduce a new spatial framework that reflects interannual variability. Therefore, the resulting spatial classification is intrinsically different from the "flyway concept." We identified two regions with distinct interannual variability of spring migration across the contiguous United States. This data-driven framework enabled us to explore the climatic cues affecting the interannual variability of migration phenology, "specific to each region" across North America. For example, our "two-region" approach allowed us to identify an east–west dipole pattern in migratory behavior linked to atmospheric Rossby waves. Also, we revealed that migration movements over the western United States were inversely related to interannual and low-frequency variability of regional temperature. A similar link, but weaker and only for interannual variability, was evident for the eastern region. However, this region was more strongly tied to climate teleconnections, particularly to the east Pacific–North Pacific (EP–NP) pattern. The results suggest that oceanic forcing in the tropical Pacific—through a chain of processes including Rossby wave trains—controls the climatic conditions, associated with bird migration over the eastern United States. Our spatial platform would facilitate better understanding of the mechanisms responsible for broadscale migration phenology and its potential future changes. [ABSTRACT FROM AUTHOR]

Published
2022
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34. Near‐term ecological forecasting for dynamic aeroconservation of migratory birds.

Author

Horton, Kyle G., Van Doren, Benjamin M., Albers, Heidi J., Farnsworth, Andrew, and Sheldon, Daniel

Subjects
*ECOLOGICAL forecasting, *MIGRATORY birds, *BIRD migration, *SURVEILLANCE radar, *LIGHT pollution
Abstract

Near‐term ecological forecasting has the potential to mitigate negative impacts of human modifications on wildlife by directing efficient action through relevant and timely predictions. We used the U.S. avian migration system to highlight ecological forecasting applications for aeroconservation. We used millions of observations from 143 weather surveillance radars to construct and evaluate a migration forecasting system for nocturnal bird migration over the contiguous United States. We identified the number of nights of mitigation required to reduce the risk of aerial hazards to 50% of avian migrants passing a given area in spring and autumn based on dynamic forecasts of migration activity. We also investigated an alternative approach, that is, employing a fixed conservation strategy based on time windows that historically capture 50% of migratory passage. In practice, during both spring and autumn, dynamic forecasts required fewer action nights compared with fixed window selection at all locations (spring: mean of 7.3 more alert days; fall: mean of 12.8 more alert days). This pattern resulted in part from the pulsed nature of bird migration captured in the radar data, where the majority (54.3%) of birds move on 10% of a migration season's nights. Our results highlight the benefits of near‐term ecological forecasting and the potential advantages of dynamic mitigation strategies over static ones, especially in the face of increasing risks to migrating birds from light pollution, wind energy infrastructure, and collisions with structures. [ABSTRACT FROM AUTHOR]

Published
2021
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35. 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

Copyright of Ornithology (Oxford University Press) is the property of Oxford University Press / USA 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
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36. Predicting bird‐window collisions with weather radar.

Author

Elmore, Jared A., Riding, Corey S., Horton, Kyle G., O'Connell, Timothy J., Farnsworth, Andrew, and Loss, Scott R.

Subjects
SURVEILLANCE radar, BIRD migration, MIGRATORY animals, MIGRATORY birds, BIRDS, FORECASTING, RADAR meteorology
Abstract

Up to 1 billion birds die annually in the U.S. from window collisions; most of these casualties represent migratory native species. Because this major mortality source likely contributes to the decline of the North American avifauna, mitigation tools are needed that accurately predict real‐time collision risk, allowing hazards to be minimized before fatalities occur.We assessed the potential use of weather surveillance radar, an emerging tool increasingly used to study and to predict bird migration, as an early warning system to reduce numbers of bird‐window collisions.Based on bird‐window collision monitoring in Oklahoma, USA, we show that radar‐derived migration variables are associated with nightly numbers of collisions. Across the entire night, numbers of collisions increased with higher migration traffic rate (i.e. numbers of birds crossing a fixed line perpendicular to migration direction), and migration variables for specific periods within the night were also related to nightly collisions.Synthesis and applications. Our study suggests that radar can be an invaluable tool to predict bird‐window collisions and help refine mitigation efforts that reduce collisions such as reducing nighttime lighting emitted from and near buildings. [ABSTRACT FROM AUTHOR]

Published
2021
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37. A weather surveillance radar view of Alaskan avian migration.

Author

Sivakumar, Ashwin H., Sheldon, Daniel, Winner, Kevin, Burt, Carolyn S., and Horton, Kyle G.

Subjects
SURVEILLANCE radar, RADAR meteorology, RADAR, CLIMATE change, REMOTE sensing, BIRD populations
Abstract

Monitoring avian migration within subarctic regions of the globe poses logistical challenges. Populations in these regions often encounter the most rapid effects of changing climates, and these seasonally productive areas are especially important in supporting bird populations—emphasizing the need for monitoring tools and strategies. To this end, we leverage the untapped potential of weather surveillance radar data to quantify active migration through the airspaces of Alaska. We use over 400 000 NEXRAD radar scans from seven stations across the state between 1995 and 2018 (86% of samples derived from 2013 to 2018) to measure spring and autumn migration intensity, phenology and directionality. A large bow-shaped terrestrial migratory system spanning the southern two-thirds of the state was identified, with birds generally moving along a northwest–southeast diagonal axis east of the 150th meridian, and along a northeast–southwest axis west of this meridian. Spring peak migration ranged from 3 May to 30 May and between, 18 August and 12 September during the autumn, with timing across stations predicted by longitude, rather than latitude. Across all stations, the intensity of migration was greatest during the autumn as compared to spring, highlighting the opportunity to measure seasonal indices of net breeding productivity for this important system as additional years of radar measurements are amassed. [ABSTRACT FROM AUTHOR]

Published
2021
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38. A place to land: spatiotemporal drivers of stopover habitat use by migrating birds.

Author

Cohen, Emily B., Horton, Kyle G., Marra, Peter P., Clipp, Hannah L., Farnsworth, Andrew, Smolinsky, Jaclyn A., Sheldon, Daniel, Buler, Jeffrey J., and Coulson, Tim

Subjects
*BIRD populations, *RADAR meteorology, *SURVEILLANCE radar, *MIGRATORY birds, *HABITATS, *BIRDS, *BIRD conservation, *AUTUMN
Abstract

Migrating birds require en route habitats to rest and refuel. Yet, habitat use has never been integrated with passage to understand the factors that determine where and when birds stopover during spring and autumn migration. Here, we introduce the stopover‐to‐passage ratio (SPR), the percentage of passage migrants that stop in an area, and use 8 years of data from 12 weather surveillance radars to estimate over 50% SPR during spring and autumn through the Gulf of Mexico and Atlantic coasts of the south‐eastern US, the most prominent corridor for North America's migratory birds. During stopovers, birds concentrated close to the coast during spring and inland in forested landscapes during autumn, suggesting seasonal differences in habitat function and highlighting the vital role of stopover habitats in sustaining migratory communities. Beyond advancing understanding of migration ecology, SPR will facilitate conservation through identification of sites that are disproportionally selected for stopover by migrating birds. [ABSTRACT FROM AUTHOR]

Published
2021
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39. MistNet: Measuring historical bird migration in the US using archived weather radar data and convolutional neural networks.

Author

Lin, Tsung‐Yu, Winner, Kevin, Bernstein, Garrett, Mittal, Abhay, Dokter, Adriaan M., Horton, Kyle G., Nilsson, Cecilia, Van Doren, Benjamin M., Farnsworth, Andrew, La Sorte, Frank A., Maji, Subhransu, Sheldon, Daniel, and Freckleton, Robert

Subjects
ARTIFICIAL neural networks, BIRD migration, WEATHER radar networks, RADAR meteorology, FALSE discovery rate, DATA libraries
Abstract

Copyright of Methods in Ecology & Evolution is the property of Wiley-Blackwell 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
2019
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40. The grand challenges of migration ecology that radar aeroecology can help answer.

Author

Bauer, Silke, Shamoun‐Baranes, Judy, Nilsson, Cecilia, Farnsworth, Andrew, Kelly, Jeffrey F., Reynolds, Don R., Dokter, Adriaan M., Krauel, Jennifer F., Petterson, Lars B., Horton, Kyle G., and Chapman, Jason W.

Subjects
ECOLOGY, RADAR, MIGRATORY animals, ENVIRONMENTAL refugees, FISH migration, CLIMATE change
Abstract

Many migratory species have experienced substantial declines that resulted from rapid and massive expansions of human structures and activities, habitat alterations and climate change. Migrants are also recognized as an integral component of biodiversity and provide a multitude of services and disservices that are relevant to human agriculture, economy and health. The plethora of recently published studies reflects the need for better fundamental knowledge on migrations and for better management of their ecological and human‐relevant effects. Yet, where are we in providing answers to fundamental questions and societal challenges? Engaging a broad network of researchers worldwide, we used a horizon‐scan approach to identify the most important challenges which need to be overcome in order to gain a fuller understanding of migration ecology, and which could be addressed using radar aeroecological and macroecological approaches. The top challenges include both long‐standing and novel topics, ranging from fundamental information on migration routes and phenology, orientation and navigation strategies, and the multitude of effects migrants may have on resident communities, to societal challenges, such as protecting or preventing migrant services and disservices, and the conservation of migrants in the face of environmental changes. We outline these challenges, identify the urgency of addressing them and the primary stakeholders – researchers, policy makers and practitioners, or funders of research. [ABSTRACT FROM AUTHOR]

Published
2019
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41. Holding steady: Little change in intensity or timing of bird migration over the Gulf of Mexico.

Author

Horton, Kyle G., Van Doren, Benjamin M., La Sorte, Frank A., Cohen, Emily B., Clipp, Hannah L., Buler, Jeffrey J., Fink, Daniel, Kelly, Jeffrey F., and Farnsworth, Andrew

Subjects
*BIRD migration, *CLIMATE change, *PHENOLOGY, *RADAR meteorology
Abstract

Quantifying the timing and intensity of migratory movements is imperative for understanding impacts of changing landscapes and climates on migratory bird populations. Billions of birds migrate in the Western Hemisphere, but accurately estimating the population size of one migratory species, let alone hundreds, presents numerous obstacles. Here, we quantify the timing, intensity, and distribution of bird migration through one of the largest migration corridors in the Western Hemisphere, the Gulf of Mexico (the Gulf). We further assess whether there have been changes in migration timing or intensity through the Gulf. To achieve this, we integrate citizen science (eBird) observations with 21 years of weather surveillance radar data (1995–2015). We predicted no change in migration timing and a decline in migration intensity across the time series. We estimate that an average of 2.1 billion birds pass through this region each spring en route to Nearctic breeding grounds. Annually, half of these individuals pass through the region in just 18 days, between April 19 and May 7. The western region of the Gulf showed a mean rate of passage 5.4 times higher than the central and eastern regions. We did not detect an overall change in the annual numbers of migrants (2007–2015) or the annual timing of peak migration (1995–2015). However, we found that the earliest seasonal movements through the region occurred significantly earlier over time (1.6 days decade−1). Additionally, body mass and migration distance explained the magnitude of phenological changes, with the most rapid advances occurring with an assemblage of larger‐bodied shorter‐distance migrants. Our results provide baseline information that can be used to advance our understanding of the developing implications of climate change, urbanization, and energy development for migratory bird populations in North America. We quantify the timing, intensity, and distribution of bird migration through one of the largest migration corridors in the Western Hemisphere, the Gulf of Mexico, by integrating citizen science (eBird) observations with weather surveillance radar data. We estimate that an average of 2.1 billion birds pass through this region each spring, with half of these individuals pass through the region in just 18 days, between April 19 and May 7. We did not detect an overall change in the annual numbers of migrants (2007–2015) or the annual timing of peak migration (1995–2015). [ABSTRACT FROM AUTHOR]

Published
2019
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42. Projected changes in wind assistance under climate change for nocturnally migrating bird populations.

Author

La Sorte, Frank A., Horton, Kyle G., Nilsson, Cecilia, and Dokter, Adriaan M.

Subjects
*CLIMATE change, *MIGRATORY birds, *NOCTURNAL birds, *WIND pressure, *ANTHROPOGENIC effects on nature
Abstract

Current climate models and observations indicate that atmospheric circulation is being affected by global climate change. To assess how these changes may affect nocturnally migrating bird populations, we need to determine how current patterns of wind assistance at migration altitudes will be enhanced or reduced under future atmospheric conditions. Here, we use information compiled from 143 weather surveillance radars stations within the contiguous United States to estimate the daily altitude, density, and direction of nocturnal migration during the spring and autumn. We intersected this information with wind projections to estimate how wind assistance is expected to change during this century at current migration altitudes. The prevailing westerlies at midlatitudes are projected to increase in strength during spring migration and decrease in strength to a lesser degree during autumn migration. Southerly winds will increase in strength across the continent during both spring and autumn migration, with the strongest gains occurring in the center of the continent. Wind assistance is projected to increase across the central (0.44 m/s; 10.1%) and eastern portions of the continent (0.32 m/s; 9.6%) during spring migration, and wind assistance is projected to decrease within the central (0.32 m/s; 19.3%) and eastern portions of the continent (0.17 m/s; 6.6%) during autumn migration. Thus, across a broad portion of the continent where migration intensity is greatest, the efficiency of nocturnal migration is projected to increase in the spring and decrease in the autumn, potentially affecting time and energy expenditures for many migratory bird species. These findings highlight the importance of placing climate change projections within a relevant ecological context informed through empirical observations, and the need to consider the possibility that climate change may generate both positive and negative implications for natural systems. We used information compiled from 143 weather surveillance radars stations within the contiguous USA to estimate the altitude, density, and direction of nocturnal migration during the spring and autumn. We intersected this information with wind projections to estimate how wind assistance is expected to change during this century under global climate change. Across the eastern and especially the central portions of the continent, the efficiency of nocturnal migration is projected to increase in the spring and decrease in the autumn, potentially affecting time and energy expenditures for many migratory bird species. [ABSTRACT FROM AUTHOR]

Published
2019
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43. Navigating north: how body mass and winds shape avian flight behaviours across a North American migratory flyway.

Author

Horton, Kyle G., Van Doren, Benjamin M., La Sorte, Frank A., Fink, Daniel, Sheldon, Daniel, Farnsworth, Andrew, and Kelly, Jeffrey F.

Subjects
*MIGRATORY birds, *BIRD migration, *BIRD behavior, *BIRD communities, *BIRD flight, *BIRD variation
Abstract

Abstract: The migratory patterns of birds have been the focus of ecologists for millennia. What behavioural traits underlie these remarkably consistent movements? Addressing this question is central to advancing our understanding of migratory flight strategies and requires the integration of information across levels of biological organisation, e.g. species to communities. Here, we combine species‐specific observations from the eBird citizen‐science database with observations aggregated from weather surveillance radars during spring migration in central North America. Our results confirm a core prediction of migration theory at an unprecedented national scale: body mass predicts variation in flight strategies across latitudes, with larger‐bodied species flying faster and compensating more for wind drift. We also find evidence that migrants travelling northward earlier in the spring increasingly compensate for wind drift at higher latitudes. This integration of information across biological scales provides new insight into patterns and determinants of broad‐scale flight strategies of migratory birds. [ABSTRACT FROM AUTHOR]

Published
2018
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44. Dual-polarization radar products for biological applications.

Author

STEPANIAN, PHILLIP M., HORTON, KYLE G., MELNIKOV, VALERY M., ZRNIĆ, DUŠAN S., and GAUTHREAUX JR., SIDNEY A.

Subjects
BIRD migration, RADAR indicators, POLARIMETRY, REMOTE sensing, BIRD populations
Abstract

The upgrade of the national network of next-generation weather surveillance radars (NEXRAD) in the United States to dual polarizations has been completed, providing three additional routine data products: total differential phase (ψDP), differential reflectivity (ZDR), and copolar correlation coefficient (ρHV). The application and interpretation of these products in the context of aerial bird, bat, and insect movements is an actively developing research front, with potential implications for ecological and conservation studies. The following conceptually derives the definition of these products specifically for NEXRAD weather surveillance radars in the case of biological scatterers. Several cases are presented that illustrate characteristic values and variability of polarimetric quantities for birds and insects, and highlight site-specific differences within the NEXRAD network. Finally, a short prospectus of future directions and applications within the field of polarimetric radar aeroecology is outlined. [ABSTRACT FROM AUTHOR]

Published
2016
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45. Extending bioacoustic monitoring of birds aloft through flight call localization with a three-dimensional microphone array.

Author

Stepanian, Phillip M., Horton, Kyle G., Hille, David C., Wainwright, Charlotte E., Chilson, Phillip B., and Kelly, Jeffrey F.

Subjects
*ANIMAL sounds, *BIOACOUSTICS, *BIRDSONGS, *BIRD communication, *BIRD behavior
Abstract

Bioacoustic localization of bird vocalizations provides unattended observations of the location of calling individuals in many field applications. While this technique has been successful in monitoring terrestrial distributions of calling birds, no published study has applied these methods to migrating birds in flight. The value of nocturnal flight call recordings can increase with the addition of three-dimensional position retrievals, which can be achieved with adjustments to existing localization techniques. Using the time difference of arrival method, we have developed a proof-of-concept acoustic microphone array that allows the three-dimensional positioning of calls within the airspace. Our array consists of six microphones, mounted in pairs at the top and bottom of three 10-m poles, arranged in an equilateral triangle with sides of 20 m. The microphone array was designed using readily available components and costs less than $2,000 USD to build and deploy. We validate this technique using a kite-lofted GPS and speaker package, and obtain 60.1% of vertical retrievals within the accuracy of the GPS measurements (±5 m) and 80.4% of vertical retrievals within ±10 m. The mean Euclidian distance between the acoustic retrievals of flight calls and the GPS truth was 9.6 m. Identification and localization of nocturnal flight calls have the potential to provide species-specific spatial characterizations of bird migration within the airspace. Even with the inexpensive equipment used in this trial, low-altitude applications such as surveillance around wind farms or oil platforms can benefit from the three-dimensional retrievals provided by this technique. [ABSTRACT FROM AUTHOR]

Published
2016
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46. Wind drift explains the reoriented morning flights of songbirds.

Author

Van Doren, Benjamin M., Horton, Kyle G., Stepanian, Phillip M., Mizrahi, David S., and Farnsworth, Andrew

Subjects
*BIRD migration, *DOPPLER radar, *REMOTE sensing equipment, *MIGRATORY birds, *SONGBIRDS, *ANIMAL behavior
Abstract

Remote sensors such as Doppler radars are providing novel insights into the migrations of diverse animal taxa, but limits in scope and sensitivity can hamper the utility of these tools. For example, studies investigating whether songbirds compensate effectively for wind displacement during nocturnal migration have been challenged by the need to assess behavior on a large scale. In addition, these studies typically overlook the potential role low-altitude diurnal flights play in dealing with unfavorable winds. In such cases, a combination of approaches—new and traditional—may be necessary to understand behavior more completely. Here, we unite ground-based visual observations with a new radar analysis method to investigate how songbirds deal with crosswinds over the northeast United States. We find that nocturnally migrating birds experienced significant wind drift, even though they often flew at 90° or more to the wind direction. Significantly, more birds undertook reoriented diurnal flights after nocturnal wind drift, and wind influence, nocturnal migration intensity, and time of season together explained the majority of variation in counts of these "morning flights." This study shows that bird behavior during migration can be strongly shaped by the danger of wind drift and that some songbird species respond to drift with reoriented diurnal migratory flights. Knowledge of birds' interactions with wind is essential for successfully modeling migratory behavior and assessing the risks associated with changing habitats and meteorological patterns. Furthermore, an understanding of the degree to which drift defines migratory behaviors may have value across animal taxa. [ABSTRACT FROM AUTHOR]

Published
2016
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47. Individual flight-calling behaviour in wood warblers.

Author

Morris, Sara R., Horton, Kyle G., Tegeler, Amy K., and Lanzone, Michael

Subjects
*WOOD warblers, *BIRD migration, *SONGBIRDS, *BIOACOUSTICS, *BIRD communication, *BIRD flight, *ANIMAL behavior
Abstract

Warblers regularly give flight calls during migration, but few studies have addressed flight-calling behaviour by individual birds. In this study, we investigated individual responses to flight calls. We hypothesized that birds would be more likely to give flight calls in response to conspecific flight calls than to heterospecific calls or to other sounds. We studied the flight-calling response of three species of warblers (magnolia warbler, Setophaga magnolia , blackpoll warbler, Setophaga striata , and yellow-rumped warbler, Setophaga coronata ) to conspecific calls, calls of one of the other two species or calls of the spring peeper, Pseudacris crucifer , as a control. Additionally, we characterized the proportion of birds calling and the rates of calling (calls/min) for five additional warbler species. We placed each bird individually into an acoustic cone in a soundproof recording studio and recorded its vocalizations before, during and after playing sound cues in the studio. In our experiment, the three species of warblers were more likely to give flight calls in response to flight calls than to the control, and they were more likely to give flight calls to conspecific calls than heterospecific calls. The eight species of warblers that heard conspecific flight calls varied in both the likelihood of giving a response and the rate of calling, and rates of calling also varied between individuals within each species. Most birds that responded gave flight calls soon after hearing flight calls. Our results are some of the first on individual flight-calling responses and flight-calling rates. [ABSTRACT FROM AUTHOR]

Published
2016
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49. Extracting Migrant Flight Orientation Profiles Using Polarimetric Radar.

Author

Stepanian, Phillip M. and Horton, Kyle G.

Subjects
*ANIMAL migration, *AIRBORNE lasers, *RADAR in archaeology, *ELECTRONIC pulse techniques, *RADAR defense networks
Abstract

Seasonal animal migration is characterized by aligned flight of airborne organisms across large spatial expanses. This large-scale alignment results in azimuthal patterns in polarimetric radar products. The following overviews some such patterns and introduces a technique for obtaining vertical profiles of migrant flight orientation by exploiting azimuthal symmetries in the polarimetric radar product of copolar correlation coefficient \rhoHV. This method is compared with several Doppler-velocity-based techniques for measuring flight direction, and a sensitivity analysis is performed. Finally, the method is applied to a case of nocturnal migration over the Southern Great Plains, demonstrating the utility of the technique in the study of animal migratory behavior within the airspace. [ABSTRACT FROM PUBLISHER]

Published
2015
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50. Seasonal variation in the effects of artificial light at night on the occurrence of nocturnally migrating birds in urban areas.

Author

La Sorte, Frank A. and Horton, Kyle G.

Subjects
FOREST canopies, CITIES & towns, BIRD populations, SPECIES diversity, NUMBERS of species, LIGHT pollution, AUTUMN
Abstract

Urban areas often contain large numbers of migratory bird species during seasonal migration, many of which are nocturnal migrants. How artificial light at night (ALAN) and urban landcover are associated with the diurnal occurrence of nocturnal migrants within urban areas across seasons has not been explored. Here, we use eBird bird occurrence information to estimate the seasonal species richness of nocturnally migrating passerines (NMP) within 333 well surveyed urban areas within the contiguous USA. We model the relationship between seasonal NMP species richness and ALAN, proportion of tree canopy cover, and proportion of impervious surface. NMP species richness reached its highest levels during spring and autumn migration and lowest during the winter and summer. Greater tree canopy cover was associated with higher NMP species richness during spring and autumn migration and the summer. A 10% increase in the proportion of tree canopy cover was associated with a 2.0% increase in NMP species richness during spring migration, a 1.8% increase during autumn migration, and a 0.9% increase during the summer. More impervious surface was associated with higher NMP species richness during the winter. A 10% increase in the proportion of impervious surface was associated with a 6.1–9.8% increase in NMP species richness. Higher ALAN was associated with lower NMP species richness during the winter and summer, and higher NMP species richness during spring and autumn migration. A 50% increase in ALAN was associated with a 3.0–3.6% decrease in NMP species richness during the winter, a 1.7% increase during spring migration, a 2.1% decrease during the summer, and a 5.0% increase during autumn migration. These findings highlight the variable effects of ALAN and urban landcover on the seasonal occurrence of NMP species in urban areas, the value of tree canopy cover during migration and the breeding season, and the importance of reducing ALAN during migration. Image 1 • Cities contained the most nocturnally migratory bird species during spring. • Light pollution reduced species numbers during the winter and summer. • Light pollution enhanced species numbers during spring and autumn migration. • Tree canopy cover enhanced species numbers during spring migration and the summer. [ABSTRACT FROM AUTHOR]

Published
2021
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