Route simulations, compass mechanisms and long-distance migration flights in birds

Bird migration has fascinated humans for centuries and routes crossing the globe are now starting to be revealed by advanced tracking technology. A central question is what compass mechanism, celestial or geomagnetic, is activated during these long flights. Different approaches based on the geometry...

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Bibliographic Details
Published in:Journal of Comparative Physiology A
Main Authors: Åkesson, Susanne, Bianco, Giuseppe
Format: Article in Journal/Newspaper
Language:English
Published: Springer 2017
Subjects:
Evolutionary Biology
Zoology
Geographic loxodrome
Magnetc loxodrome
Magnetoclinic route
Route simulations
Sun compass route
Arctic
Online Access:https://lup.lub.lu.se/record/083b7cf5-01c2-4861-8be4-cbce54e84b75
https://doi.org/10.1007/s00359-017-1171-y
Description
Summary:Bird migration has fascinated humans for centuries and routes crossing the globe are now starting to be revealed by advanced tracking technology. A central question is what compass mechanism, celestial or geomagnetic, is activated during these long flights. Different approaches based on the geometry of flight routes across the globe and route simulations based on predictions from compass mechanisms with or without including the effect of winds have been used to try to answer this question with varying results. A major focus has been use of orthodromic (great circle) and loxodromic (rhumbline) routes using celestial information, while geomagnetic information has been proposed for both a magnetic loxodromic route and a magnetoclinic route. Here, we review previous results and evaluate if one or several alternative compass mechanisms can explain migration routes in birds. We found that most cases could be explained by magnetoclinic routes (up to 73% of the cases), while the sun compass could explain only 50%. Both magnetic and geographic loxodromes could explain <25% of the routes. The magnetoclinic route functioned across latitudes (1°S–74°N), while the sun compass only worked in the high Arctic (61–69°N). We discuss the results with respect to orientation challenges and availability of orientation cues.

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