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  • This 16th century woodblock shows fisherman pulling a big netload of hibernating swallows

  • from a frozen-over lake. If you haven't heard about how swallows hibernate through the winter

  • at the bottom of lakes, it's because they don't. But, for thousands of years, hibernation

  • was one of the leading theories to explain where birds went between fall and spring.

  • Another theory was that the birds left entirely and flew far away for the winter -- we call

  • this "migration" -- but they didn't have a clue where the birds would go. For example,

  • a pamphlet from 1703 suggested that they went to the moon.

  • The first real clues about where migratory birds actually go during the winter -- hint:

  • it's not the moon or the bottom of a frozen lake -- came around 1900, thanks to a Danish

  • teacher's technique of attaching marked aluminum rings to birds' legs and then re-releasing

  • them. Each recapture or sighting of a banded bird put a dot on the map, and soon, long-distance

  • earthly migrations were confirmed when a White stork that had been banded in Hungary was

  • found dead in South Africa. But banding can only tell researchers about single points

  • along a bird's migratory path -- not what happens BETWEEN those points.

  • More recently, researchers finally started to get a better view -- a bird's-eye view,

  • in fact -- of these annual migrations, when a bald eagle in Maryland was captured and

  • fitted with a transmitter powerful enough to send signals to a pair of orbiting satellites.

  • Satellite tracking revealed details of some remarkable migrations, like the bar-tailed

  • godwit's annual flight from Alaska to New Zealand, during which the bird covers 11,000

  • km in about eight days without a single stop. But there's a serious limitation to satellite

  • tracking devices: even with modern technology, transmitters with enough oomph to send signals

  • to satellites are still far too heavy for small songbirds.

  • A slight improvement is to use gps recorders, which can be smaller because they receive

  • rather than send signals to satellites -- but they're still too heavy for the smallest birds.

  • Luckily, scientists have been clever enough to realize they don't need satellite tracking

  • at all! Instead, we can fit birds with a tiny light-level recorder, clock, and memory chip,

  • which together weigh as much as a raisin. Lightweight light-recorders don't broadcast

  • so we need to recapture the birds to get the data, but we can then use ancient navigation

  • methods to reconstruct the bird's daily location over the course of its journey: the length

  • of each day is an indicator of latitude, and the time halfway between sunset and sunrise

  • (that is, noon) is an indicator of longitude.

  • These clever geolocators have shed light on the world's speediest migration: the Great

  • snipe, which weighs about 170 grams (half a can of soda-pop), high-tails it from Sweden

  • to Central Africa in just three days, averaging 95 km per hour.

  • Another marathon migrator, the Arctic tern, has long been credited with the longest migration

  • for its annual round-trip flight between the Arctic and Antarctican estimated 40,000

  • km. But recent data from light-level geolocators show that terns actually travel more than

  • twice as far each year, possibly to take advantage of prevailing winds.

  • This means that arctic terns can rack up over 2 and a half million kilometers of flight

  • in a lifetime -- enough for three round trips to the moon. But as far as we know, they haven't

  • actually made it there yet.

This 16th century woodblock shows fisherman pulling a big netload of hibernating swallows

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