Abstract
Despite the wealth of studies on seasonal movements of birds between southern nonbreeding locations and High Arctic breeding locations, the key mechanisms of navigation during these migrations remain elusive. A flight along the shortest possible route between pairs of points on a sphere (‘orthodrome’) requires a bird to be able to assess its current location in relation to its migration goal and to make continuous adjustment of heading to reach that goal. Alternatively, birds may navigate along a vector with a fixed orientation (‘loxodrome’) based on magnetic and/or celestial compass mechanisms. Compass navigation is considered especially challenging for summer migrations in Polar regions, as continuous daylight and complexity in the geomagnetic field may complicate the use of both celestial and magnetic compasses here. We examine the possible use of orientation mechanisms during migratory flights across the Greenland Icecap. Using a novel 2 g solar‐powered satellite transmitter, we documented the flight paths travelled by a female red knot Calidris canutus islandica during two northward and two southward migrations. The geometry of the paths suggests that red knots can migrate across the Greenland Icecap along the shortest‐, orthodrome‐like, path instead of the previously suggested loxodrome path. This particular bird's ability to return to locations visited in a previous year, together with its sudden course changes (which would be appropriate responses to ambient wind fields), suggest a map sense that enables red knots to determine location, so that they can tailor their route depending on local conditions.
Highlights
In response to predictable changing environmental conditions, many birds seasonally migrate between two places on Earth, e.g. commuting from high latitude breeding grounds to lower latitude non-breeding grounds (Alerstam 1990a, Berthold et al 2003, Winkler et al 2016)
In 2016 Paula departed from the Wadden Sea on 17 May, i.e. 25 days after release, and flew nonstop to western Iceland, where she moved among multiple nearby staging sites, all known for red knots (Wilson 1981, Gudmundsson and Gardarsson 1992, Morrison and Wilson 1992, Wilson and Morrison 1992)
At high latitudes the use of a magnetic compass and a time-compensated sun compass could lead migrants along geographic paths that closely resemble orthodromes (Alerstam 1990b, Alerstam et al 1990)
Summary
In response to predictable changing environmental conditions, many birds seasonally migrate between two places on Earth, e.g. commuting from high latitude breeding grounds to lower latitude non-breeding grounds (Alerstam 1990a, Berthold et al 2003, Winkler et al 2016). Vector navigation enables migrating birds to maintain a pre-determined orientation (Able 1995, Guilford et al 2011, Gould and Grant Gould 2012, Hansson and Åkesson 2014, Åkesson and Bianco 2016) and orient along geographicand/or magnetic loxodrome routes ( called ‘rhumblines’). These routes, by definition, are longer than orthodromes, but may be easier to achieve because of the constant heading (Imboden and Imboden 1972, Gudmundsson and Alerstam 1998)
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