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Geolocators reveal migratory connectivity between wintering and breeding areas of Golden‐winged WarblersJournal of Field Ornithology, 88
William DeLuca, B. Woodworth, C. Rimmer, P. Marra, P. Taylor, K. McFarland, S. Mackenzie, Ryan Norris (2015)
Transoceanic migration by a 12 g songbirdBiology Letters, 11
Eldar Rakhimberdiev, A. Saveliev, T. Piersma, Julia Karagicheva (2017)
FLightR: an r package for reconstructing animal paths from solar geolocation loggersMethods in Ecology and Evolution, 8
B. Stutchbury, S. Tarof, Tyler Done, Elizabeth Gow, P. Kramer, J. Tautin, J. Fox, V. Afanasyev (2009)
Tracking Long-Distance Songbird Migration by Using GeolocatorsScience, 323
(2017)
R: a language and environment for statistical computing
J. Boland (1990)
Leapfrog migration in north American shorebirds : intra- and interspecific examplesThe Condor, 92
C. Bell (1997)
Leap-frog migration in the fox sparrow : Minimizing the cost of spring migrationThe Condor, 99
Andrew Pillar, P. Marra, Nancy Flood, M. Reudink (2015)
Moult migration in Bullock’s orioles (Icterus bullockii) confirmed by geolocators and stable isotope analysisJournal of Ornithology, 157
P. Ekstrom (2004)
An advance in geolocation by lightMemoirs of National Institute of Polar Research. Special issue, 58
M. Webster, P. Marra, S. Haig, S. Bensch, R. Holmes (2002)
Links between worlds: unraveling migratory connectivityTrends in Ecology and Evolution, 17
G. Kramer, H. Streby, S. Peterson, Justin Lehman, D. Buehler, P. Wood, Darin Mcneil, Jeffery Larkin, D. Andersen (2017)
Nonbreeding isolation and population-specific migration patterns among three populations of Golden-winged WarblersThe Condor, 119
M. Boulet, H. Gibbs, K. Hobson (2006)
Integrated Analysis of Genetic, Stable Isotope, and Banding Data Reveal Migratory Connectivity and Flyways in the Northern Yellow Warbler (Dendroica petechia; aestiva Group)Ornithological Monographs, 61
Nathan Cooper, M. Hallworth, P. Marra (2017)
Light-level geolocation reveals wintering distribution, migration routes, and primary stopover locations of an endangered long-distance migratory songbirdJournal of Avian Biology, 48
M. Hallworth, P. Marra (2015)
Miniaturized GPS Tags Identify Non-breeding Territories of a Small Breeding Migratory SongbirdScientific Reports, 5
J. H. Rappole (2013)
The avian migrant: the biology of bird migration
Ruth Bennett, Sara Swarthout, Jeffrey Bolsinger, A. Rodewald, K. Rosenberg, Ronald Rohrbaugh (2017)
Extreme genetic similarity does not predict non‐breeding distribution of two closely related warblersJournal of Field Ornithology, 88
Duncan (1985)
The Yellow Warbler: a diurnal circum-Gulf fall migrantFlorida Field Naturalist, 13
Dustin Rubenstein, C. Chamberlain, Richard Holmes, Matthew Ayres, Jacob Waldbauer, Gary Graves, Noreen Tuross (2002)
Linking Breeding and Wintering Ranges of a Migratory Songbird Using Stable IsotopesScience, 295
H. Streby, T. McAllister, S. Peterson, G. Kramer, Justin Lehman, D. Andersen (2015)
Minimizing marker mass and handling time when attaching radio-transmitters and geolocators to small songbirds, 117
K. Fraser, A. Shave, A. Savage, A. Ritchie, K. Bell, J. Siegrist, J. Ray, K. Applegate, M. Pearman (2017)
Determining fine‐scale migratory connectivity and habitat selection for a migratory songbird by using new GPS technologyJournal of Avian Biology, 48
(2012)
SAS version 9.4
Eldar Rakhimberdiev, D. Winkler, E. Bridge, N. Seavy, D. Sheldon, T. Piersma, A. Saveliev (2015)
A hidden Markov model for reconstructing animal paths from solar geolocation loggers using templates for light intensityMovement Ecology, 3
Erich Bächler, S. Hahn, M. Schaub, R. Arlettaz, L. Jenni, J. Fox, V. Afanasyev, F. Liechti (2010)
Year-Round Tracking of Small Trans-Saharan Migrants Using Light-Level GeolocatorsPLoS ONE, 5
P. Ekstrom (2007)
Error measures for template-fit geolocation based on lightDeep-sea Research Part Ii-topical Studies in Oceanography, 54
W. H. Wilson (2013)
The Birds of North America
F. Salmonsen (1955)
The evolutionary significance of bird migration, 22
D. Norris, P. Marra, G. Bowen, L. Ratcliffe, J. Royle, T. Kyser (2006)
Migratory connectivity of a widely distributed songbird, the American redstart (Setophaga ruticilla)Ornithological Monographs, 61
S. Yezerinac, P. Weatherhead, P. Boag (1996)
Cuckoldry and lack of parentage-dependent paternal care in yellow warblers: a cost–benefit approachAnimal Behaviour, 52
J. H. Rappole, A. R. Tipton (1991)
New harness design for attachment of radio transmitters to small passerines, 62
M. Hallworth, M. Hallworth, T. Sillett, S. Wilgenburg, K. Hobson, P. Marra (2015)
Migratory connectivity of a Neotropical migratory songbird revealed by archival light-level geolocators.Ecological applications : a publication of the Ecological Society of America, 25 2
Eldar Rakhimberdiev, Nathan Senner, M. Verhoeven, D. Winkler, W. Bouten, T. Piersma (2016)
Comparing inferences of solar geolocation data against high-precision GPS data: annual movements of a double-tagged black-tailed godwitJournal of Avian Biology, 47
Jared Wolfe, Erik Johnson (2015)
Geolocator reveals migratory and winter movements of a Prothonotary WarblerJournal of Field Ornithology, 86
S. Clegg, J. Kelly, Mari Kimura, T. Smith (2003)
Combining genetic markers and stable isotopes to reveal population connectivity and migration patterns in a Neotropical migrant, Wilson's warbler (Wilsonia pusilla)Molecular Ecology, 12
E. Bridge, J. Kelly, A. Contina, R. Gabrielson, R. Maccurdy, D. Winkler (2013)
Advances in tracking small migratory birds: a technical review of light-level geolocationJournal of Field Ornithology, 84
(2016)
ArcGIS version 10.4.1
Yellow Warblers (Setophaga petechia) are abundant breeding birds in North America, but their migratory and non‐breeding biology remain poorly understood. Studies where genetic and isotopic techniques were used identified parallel migration systems and longitudinal segregation among eastern‐ and western‐breeding populations of Yellow Warblers in North America, but these techniques have low spatial resolution. During the 2015 breeding season, we tagged male Yellow Warblers breeding in Maine (N = 10) and Wisconsin (N = 10) with light‐level geolocators to elucidate fine‐scale migratory connectivity within the eastern haplotype of this species and determine fall migration timing, routes, and wintering locations. We recovered seven of 20 geolocators (35%), including four in Maine and three in Wisconsin. The mean duration of fall migration was 49 d with departure from breeding areas in late August and early September and arrival in wintering areas in mid‐October. Most individuals crossed the Gulf of Mexico to Central America before completing the final eastward leg of their migration to northern South America. Yellow Warblers breeding in Maine wintered in north‐central Colombia, west of those breeding in Wisconsin that wintered in Venezuela and the border region between Brazil, Colombia, and Venezuela. Our results provide an example of crosswise migration, where the more easterly breeding population wintered farther west than the more westerly breeding population (and vice versa), a seldom‐documented phenomenon in birds. Our results confirm earlier work demonstrating that the eastern haplotype of northern Yellow Warblers winters in northern South America, and provide novel information about migratory strategies, timing, and wintering locations of birds from two different populations.
Journal of Field Ornithology – Wiley
Published: Jan 1, 2018
Keywords: ; ; ; ;
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