Tracking individual birds via satellite
Three new technologies are rapidly expanding what we know about bird migration. The first is satellite telemetry of bird movement. Researchers fit birds with small solar-powered transmitters, which send data on the birds’ locations to a satellite and then on to a scientist’s office computer. The scientist can learn where a bird is, the route it took to get there, and how fast it travels.
For example, the bar-tailed godwit, a pigeon-size shorebird, breeds in Alaska and then migrates to New Zealand. Satellite transmitters show that godwits often fly nonstop from Alaska to New Zealand. Recently, a godwit set the record for the longest nonstop flight by a land bird: 8,100 miles in 10 days, from Alaska to Australia.
Satellite telemetry studies show how much individual birds, even those from the same breeding location, vary in their migratory behavior. Individual differences in migratory behavior are probably due to differences in physical condition, learning, experience, and personal preferences.
Another shorebird, the whimbrel, also makes a phenomenally long journey over the ocean. Satellite telemetry has shown that some whimbrels travel from northwest Canada, across the North American continent to Canada’s east coast, then set off over the Atlantic Ocean on a 3,400-mile, six-day, nonstop flight to the coast of Brazil. In total, they may travel 6,800 miles.
Sadly, hunters kill some of these birds when they land to rest on islands in the Lesser Antilles. The unfortunate fate of two satellite-tracked whimbrels has catalyzed a campaign to tighten regulations on shorebird hunting in the Caribbean.
Geotagging small birds
Many birds are too small to carry a satellite transmitter. Given the energetic effort required for migration, a device must weigh less than 5% of a bird’s body weight, and many migratory songbirds weigh under 0.7 ounces.
An ingenious solution for small birds is a geolocator tag, or geologger—a tiny device that simply records time, location, and presence or absence of sunlight. Scientists know the timing of sunrise and sunset on a given date, so they can calculate a bird’s location on that date to within about 125 miles.
Birds carrying geologgers must be recaptured to download the data. That means the bird must survive a migration round trip and return to the same place where it was first captured and tagged. Amazingly, many geologger-tagged small birds do.
Geologgers have shown that Blackpoll warblers—small songbirds that breed in the boreal forests of North America—fly long distances over the Atlantic in fall, heading to the Amazon basin. Birds breeding in eastern North America head out over the Atlantic in maritime Canada or the northeastern U.S. and make a 60-hour, nonstop, 1,500-mile flight to the Greater Antilles. There they rest and recuperate, then continue across the Caribbean to South America.
Blackpolls breeding in Alaska fly across the North American continent before leaving shore on the Atlantic coast and flying to South America. In total, they journey 6,600 miles over 60 days.
Even more amazing, geologgers show that another small songbird, the northern wheatear, migrates from North America to subSaharan Africa. Wheatears that breed in Alaska fly 9,100 miles across Asia to East Africa, taking three months to do so. Those breeding in eastern Canada journey 4,600 miles across the Atlantic to Europe and then on to West Africa—including a 2,100-mile , four-day, nonstop, overwater flight.
Recording birds’ night migration calls
Two hours after sunset in fall, I like to sit outside and listen to birds migrating overhead. Most birds migrate at night, and many give a species-specific “chit,” “zeep” or other call-note while in flight. The calls may serve to keep migrating flocks together, including different species heading to the same destination.
Ornithologists are using automated passive acoustic recording to study these nocturnal calls and identify the species or group of related species that make each sound. The technology is a microphone directed at the sky, connected to a computer that continuously records the sound stream, and is aided by sound recognition software. Sometimes it reveals migrants overhead that are rarely seen on the ground.
Nick Kachala, an honors student in my lab, set up recording units on three university properties in the fall of 2021. One of the most common migrants recorded was the gray-cheeked thrush, a shy bird of the northern boreal forest that is rarely seen in the northeast U.S. during fall migration. He also detected the dickcissel, a grassland bird that I have never seen in our area.
Many birdwatchers are now building do-it-yourself backyard recording units to identify the birds flying over their homes during migration.
Conserving migratory birds
Radar monitoring indicates that the number of North American migratory birds declined by 14% between 2007 and 2017. There probably are multiple causes, but habitat loss is likely the principal culprit.
Satellite telemetry and geologgers show that there are special stopover sites along migration routes where migrants rest and refuel, such as the Texas Gulf Coast, the Florida Panhandle, and Mexico’s Yucatan Peninsula. Conservation experts widely agree that to protect migratory birds, it is critical to conserve these sites.
Effective conservation measures require knowing where and how birds migrate, and what dangers they face during migration. Ornithologists, using these new technologies, are learning things that will help to stop and reverse the global decline in migratory birds.
Tom Langen is a professor of biology at Clarkson University.
This article is republished from The Conversation under a Creative Commons license. Read the original article.
