Phenology of nocturnal avian migration has shifted at the continental scale

Climate change induced phenological shifts in primary productivity result in trophic mismatches for many organisms 1 – 4 , with broad implications for ecosystem structure and function. For birds that have a synchronized timing of migration with resource availability, the likelihood that trophic mism...

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Veröffentlicht in:	Nature climate change 2020-01, Vol.10 (1), p.63-68
Hauptverfasser:	Horton, Kyle G., La Sorte, Frank A., Sheldon, Daniel, Lin, Tsung-Yu, Winner, Kevin, Bernstein, Garrett, Maji, Subhransu, Hochachka, Wesley M., Farnsworth, Andrew
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Schlagworte:	631/158/2039 631/158/2165/2457 631/158/851 Autumn Bird migration Birds Climate Change Climate Change/Climate Change Impacts Climatic analysis Earth and Environmental Science Ecosystem structure Environment Environmental Law/Policy/Ecojustice Environmental Sciences Environmental Sciences & Ecology Environmental Studies Letter Life Sciences & Biomedicine Meteorology & Atmospheric Sciences Migratory species Physical Sciences Primary production Radar Radar data Remote sensing Resource availability Science & Technology Spring Spring (season) Structure-function relationships Surface temperature Surveillance radar Weather
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creator	Horton, Kyle G. La Sorte, Frank A. Sheldon, Daniel Lin, Tsung-Yu Winner, Kevin Bernstein, Garrett Maji, Subhransu Hochachka, Wesley M. Farnsworth, Andrew
description	Climate change induced phenological shifts in primary productivity result in trophic mismatches for many organisms 1 – 4 , with broad implications for ecosystem structure and function. For birds that have a synchronized timing of migration with resource availability, the likelihood that trophic mismatches may generate a phenological response in migration timing increases with climate change 5 . Despite the importance of a holistic understanding of such systems at large spatial and temporal scales, particularly given a rapidly changing climate, analyses are few, primarily because of limitations in the access to appropriate data. Here we use 24 years of remotely sensed data collected by weather surveillance radar to quantify the response of a nocturnal avian migration system within the contiguous United States to changes in temperature. The average peak migration timing advanced in spring and autumn, and these changes were generally more rapid at higher latitudes. During spring and autumn, warmer seasons were predictive of earlier peak migration dates. Decadal changes in surface temperatures predicted spring changes in migratory timing, with greater warming related to earlier arrivals. This study represents one of the first system-wide examinations during two seasons and comprises measures from hundreds of species that describe migratory timing across a continent. Our findings provide evidence of spatially dynamic phenological shifts that result from climate change. Climate change affects the timing of bird migration, which can lead to mismatch with resource availability. Migration occurred earlier in spring and autumn in the United States during the past 24 years; warming led to later arrival in the western Unites States and earlier arrival in the rest of the country.
doi_str_mv	10.1038/s41558-019-0648-9
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Decadal changes in surface temperatures predicted spring changes in migratory timing, with greater warming related to earlier arrivals. This study represents one of the first system-wide examinations during two seasons and comprises measures from hundreds of species that describe migratory timing across a continent. Our findings provide evidence of spatially dynamic phenological shifts that result from climate change. Climate change affects the timing of bird migration, which can lead to mismatch with resource availability. 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The average peak migration timing advanced in spring and autumn, and these changes were generally more rapid at higher latitudes. During spring and autumn, warmer seasons were predictive of earlier peak migration dates. Decadal changes in surface temperatures predicted spring changes in migratory timing, with greater warming related to earlier arrivals. This study represents one of the first system-wide examinations during two seasons and comprises measures from hundreds of species that describe migratory timing across a continent. Our findings provide evidence of spatially dynamic phenological shifts that result from climate change. Climate change affects the timing of bird migration, which can lead to mismatch with resource availability. 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Clim. Chang</stitle><stitle>NAT CLIM CHANGE</stitle><date>2020-01-01</date><risdate>2020</risdate><volume>10</volume><issue>1</issue><spage>63</spage><epage>68</epage><pages>63-68</pages><issn>1758-678X</issn><eissn>1758-6798</eissn><abstract>Climate change induced phenological shifts in primary productivity result in trophic mismatches for many organisms 1 – 4 , with broad implications for ecosystem structure and function. For birds that have a synchronized timing of migration with resource availability, the likelihood that trophic mismatches may generate a phenological response in migration timing increases with climate change 5 . Despite the importance of a holistic understanding of such systems at large spatial and temporal scales, particularly given a rapidly changing climate, analyses are few, primarily because of limitations in the access to appropriate data. Here we use 24 years of remotely sensed data collected by weather surveillance radar to quantify the response of a nocturnal avian migration system within the contiguous United States to changes in temperature. The average peak migration timing advanced in spring and autumn, and these changes were generally more rapid at higher latitudes. During spring and autumn, warmer seasons were predictive of earlier peak migration dates. Decadal changes in surface temperatures predicted spring changes in migratory timing, with greater warming related to earlier arrivals. This study represents one of the first system-wide examinations during two seasons and comprises measures from hundreds of species that describe migratory timing across a continent. Our findings provide evidence of spatially dynamic phenological shifts that result from climate change. Climate change affects the timing of bird migration, which can lead to mismatch with resource availability. 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title	Phenology of nocturnal avian migration has shifted at the continental scale
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