The Science of Birds - Migration in Birds
Episode Date: September 22, 2020Episode: 4SummaryThe annual long-distance movements of birds are amazing feats of endurance and navigation.Learn about the various forms of migration and other annual movements in birds. We’ll cover... many concepts related to migration, including timing and orientation, staging areas, and flyways.Research CitationsThe Beijing Cuckoo ProjectLinks to Some Things Mentioned in this EpisodePfeilstorchLink to this episode on the Science of Birds websiteSupport the show
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If you asked a European person in the 1700s, where new birds go in the winter?
They might just look at you with a blank stare, then shake their head and walk away.
Or feeling more helpful, they might refer you to a pamphlet published in 1703,
succinctly titled,
An essay toward the probable solution of this question,
whence come the stork and the turtle dove, the crane, and the swallow,
when they know and observe the appointed time of their coming.
Yes, that's the title.
The answer given in the pamphlet?
Birds fly to the moon in the winter.
Silly, right?
Well, sure.
But before scientists had actually studied birds and the moon more carefully,
this would have been about as reasonable as any other answer.
Another explanation in ye olden days was that birds hibernate at the bottom of the sea
or while buried in swamp mud.
But in 1822, a hunter in Germany shot and killed a white stork
and found that the bird already had a large arrow lodged in its neck.
And it turned out that the arrow came from Central Africa.
This lucky, not-so-lucky stork gave the world its first good piece of evidence
that birds in the northern hemisphere often undertake long journeys south in the winter.
This bird was dubbed a fielstorch, which means aerostork in German.
I'm sure I'm not pronouncing that very well.
Feilstork.
Amazingly, this bird was not one of a kind.
About 25 of these file storks have turned up since 1822.
Those are some pretty hardcore birds
to survive getting impaled with an arrow
and then flying thousands of miles north
with the arrow stuck in your body?
Crazy.
These days, we don't need to puncture birds with arrows
to understand their annual movements.
Thankfully, we now have amazing tools like GPS trackers
that provide precise location info
without any harm to the animals.
We live in a time when research
on bird migration has given us amazingly detailed pictures of just where birds are going
and how they get there.
Hello and welcome.
This is the Science of Birds.
I'm your host, Ivan Philipson.
The Science of Birds podcast is a down-to-earth discussion of fascinating topics in the
wonderful world of bird biology.
This is ornithology for lifelong learners, bird nerds, and those who are simply bird-curious.
Today's episode is about migration.
This is one of the most amazing things about birds.
They're seemingly miraculous feats of orientation and endurance on long-distance annual flights.
This is a big topic, so I can't do a deep dive into all things migration here,
not unless you want to listen to a six-hour podcast episode.
Instead, this will be an overview of migration in birds.
In future episodes, I can drill down into some of the specific sub-examination.
topics of migration. Sound like a plan? Cool. Let's go ahead and get into it.
In general, birds are incredibly mobile beasts, given that they fly. Compared to us lowly
earthbound creatures, birds are free to go where they please, but they don't just fly around the
planet aimlessly. Instead, a range of distinct movement types and patterns are seen among the
earth's 10,000 or so bird species. At the smallest geographic and temporal scales, birds move around
in their local habitats over the course of a day. They forage for food, seek shelter from predators
and the weather. They defend territories, look for mates, and tend to their nests. Another type of
movement is the one that every bird makes once in their lifetime. Young birds begin their lives
in one location and then venture forth into the unknown, often on their own, away from where they were
born. This movement is called dispersal. Some species tend to disperse long distances, others stay
very close to where they hatched. Humans disperse too. I live in Oregon now, but I was born in
California, where I left my dear old mom. Some other guys in their 40s might still live with their
moms. Those are cases of non-dispersal. And then we have migration, which is our topic today.
This is the regular seasonal movement undertaken by birds. In most cases, it goes from North the
South and vice versa.
Migration, as you'll see, comes in an assortment of flavors.
Migration is an annual movement, repeated every year,
but it's not the only type of annual movement in birds.
One type of annual movement is that of no movement, otherwise known as residents.
Most of the world's bird species, perhaps as much as 80%, don't technically migrate.
Most just hang around in their usual haunts, no matter what the season is.
They may have a particular season for breeding, but they don't travel very far to take care of that business.
We call these homebody birds residents.
The majority of bird species in the tropics are residents.
And since most of the world's bird diversity is concentrated in the tropics,
it isn't surprising that the bird species showing true migration are actually in the minority at the global scale.
Side note here, if you'd like to learn some more about the distribution of bird diversity,
check out episode three of this podcast. So we have resident birds, but the other 20 to 40% of
bird species are not residents. They go through some kind of migration. The first type of
true migration to discuss here is facultative migration. This is where a bird species migrates
in some years, but not in others. Birds of this sort may spend the entire year in one location
when conditions are normal and good.
But if conditions get lousy in a given year,
if, for example, there's a particularly harsh winter
and or food is in short supply,
individuals may then choose to migrate some distance,
perhaps even a long way to greener pastures.
Choose is the keyword here.
These birds assess the local current conditions
and decide to stay put or migrate.
Species with facultative migration
often depend on food resources
that can vary widely in availability
from one year to the next. For example, migration in pine siskins is somewhat erratic across
the years, depending on where their food is. These little birds sometimes show up in unexpected
places in years when there are failures of cone crops and other seeds in the siskins' normal winter
range. In other places, they don't migrate very far, if at all, when food is plentiful. These boisterous
members of the Finch family are facultative migrants. Also, I love the scientific name for the species,
Spinaspinus. Then we have obligate migration, which is probably what many of us think of when we hear
the word migration. This is where a species migrates predictably between two regions every year.
Obligate migrants spend part of the year in a breeding range and the rest of the year in a non-breeding
range, what is for some species called a winter range. For an obligate migrant species, all or nearly
all individual birds make the annual journey there and back again. They're hardwired to migrate.
They are obligated by their genes to make their annual journeys. There are many familiar birds
that are obligate migrants. Swainson's hawk is a North American raptor that spends the non-breeding
season in the pompous grasslands of southern South America. Almost every individual Swainson's
Hawk makes the epic round-trip journey of over 12,000 miles to South America every year.
A European example of an obligate migrant is the garden warbler, which flies to southern Africa every winter, more or less like clockwork.
Another form of annual movement is nomadism.
This is where members of a species move about over the course of a year in a much less predictable pattern.
These birds are scouring the landscape for some kind of vital resource that is only sporadically available.
This resource is usually food.
This food could be local infestations of insect prey or a plant.
species that has boom and bust cycles of fruit or seed production.
Nomadism isn't technically migration because these movements aren't predictable.
They change from year to year and are entirely dependent on the location and availability of
that key resource.
The Red Crossbill is a classic example of a nomadic species across the Northern Hemisphere.
Flocks of crossbills criss-cross vast areas of coniferous forest as they look for cone crops.
Perhaps not surprisingly, many desert birds are nomadic.
For example, the gray teal, a type of duck, is nomadic in the arid parts of Australia,
moving from place to place in response to water and food availability.
Most of the bird species with true migration are not obligate migrants across their whole range.
Instead, they display different migration types in different geographic areas.
Such a species might have some resident populations while also having
populations that migrate, either facultatively or obligately. This is called partial migration,
where populations of a single species display different movement types across the species range.
Familiar species that are partial migrants include Buick's Wren in North America
and the European Robin and Eurasian Kestrel on the other side of the Atlantic.
Why do birds migrate?
Why go through all the trouble?
This is a big question, and we don't fully understand all the ends and outs of how or why migration evolved in birds.
It's complex.
But it's reasonable to assume that migration must improve the chances of survival and reproductive success of the species that migrate.
Otherwise, it wouldn't have evolved in the first place.
The best explanation for why migration evolved in birds is that it allows,
them to take advantage of seasonal differences in environments around the world. Some places on
earth are great for mating and raising a family, but only at certain times of the year. Other places
are better for finding plenty of food and shelter during the non-breeding season. This is all
about trade-offs and optimization. Migration has huge costs and risks involved, so these have
to be offset by great benefits, at least on average, in the long term. Now, if you're
like me, you sometimes lie awake at night thinking about small songbirds that lived 15,000 years ago
in Equatorial Africa. Let's think about such a bird species now as we ponder how migration
might have evolved since the end of the last ice age. These birds might have made short-distance
annual movements across their tropical homelands, looking for seasonably variable food. As the planet
warmed and glaciers melted away across Europe, vast new lands opened up to the north. Some of these little
birds ended up exploring the newly ice-free Europe. There they found little competition for
nesting space or food resources. Predators and diseases were few, and the summer days were extra
long. These pioneer birds had advantages that allowed them to produce more offspring than their
friends who never left Central Africa. Natural selection favored the birds that migrated back and
forth between the two continents and, eventually, the species became fully migratory.
Such a scenario may or may not have been how it all went down.
Some researchers have made the case that migration evolved most recently in northern birds
who expanded southward, rather than the other way around, as in our little story.
And, most likely, the ability and drive to migrate long distances didn't originate only 15,000
years ago. Scientists think that migration goes way back millions of years and is likely a primitive
characteristic in birds. Migration behavior has probably been lost and resumed across many
bird lineages again and again as the world's environments have continued to change.
True migration comes in a few flavors. Some major patterns of migration can be seen across the
avian world. First off, migration distances vary among species. There are short, medium, and long-distance
migrants. The range here is huge, with some birds making annual migrations of only a few tens of miles,
while others literally travel from one end of the earth to the other. Another way that migration
varies among species is by pacing. We have hops, skips, and jumps. Birds that hop are the ones that
assume the most leisurely pace, making numerous short stops on their migration route. Those that
skip make fewer stops, maybe three or four. And birds that jump are fast-paced migrants,
resting at only one or two places along the way. Swainson's thrush, named for the same English
ornithologist as the hawk I talked about earlier, is an example of a hopping species. This bird
makes a series of short stops on its migration, usually lasting from one to four days.
At the other end of the spectrum, we have species known to jump.
The bar-tailed Godwit is a champion jumper.
These crazy shorebirds can fly non-stop from Alaska to New Zealand in only nine days.
That's a distance of over 6,000 miles.
Many species have one particular migration pathway in the spring,
as they fly toward their breeding areas,
but then they travel a different path in the fall.
This is particularly true of songbirds.
When you look at the migration paths traveled over the course of the year for one of these
species, you see that they form a loop. Why would birds travel different routes as they come and go?
The best explanation is that because there are seasonal differences in weather and wind
conditions at different places, it makes sense to follow the path of least resistance in each season,
that is, the path where you're more likely to have a tailwind and good weather.
These loop migration paths could also come from food availability, which can vary by
season and location. The feisty little firecracker known as the Rufus hummingbird
displays a looping migration pattern. In spring, these hummers fly north from Mexico to the
Pacific Northwest following the Pacific coast. Then they work their way back down to Mexico in the
fall, this time through the Rocky Mountains, where they refuel on nectar from late-blooming
mountain wildflowers. All of the movement we've been talking about so far has been in the
horizontal dimension across latitudes and longitudes. But for some bird species, annual movements
in the vertical dimension are the most significant. This is what we call altitudinal migration.
Altitudinal migrants move up slope to higher elevations at one time of year, and then back down
to lower elevations for the rest of the year. Birds might do this to reach high elevation
habitats that are accessible in only the warmer months, or they might be taking advantage of different
food resources that vary by elevation and season. Altitudinal migration is more common among
species in the tropics, and food availability is usually the driver in those regions. A couple of
northern latitude examples of birds with altitudinal migration are the varied thrush in North America
and the wall creeper in Eurasia. Both species live up in the mountains in the warm months,
but retreat to lower elevations in the winter. Not all members of a species do exactly the same
thing every year. There's individual variation, some wiggle in the migration paths taken.
On top of that, distances traveled often vary between males and females, as well as between
juveniles and adults. For example, in dark-eyed juncos, adults migrate farther than young birds,
and females migrate farther than males. The same is true for Eurasian blackbirds and quite a few
other songbirds for which we have data. So one theme here is that of variation. Variation and
complexity are recurring themes in nature. This keeps things exciting, keeps us on our toes.
Anyway, migration paths and pacing in birds often show variation across individuals,
sexes, age classes, different breeding populations, and even subsets of those populations.
Now, I'd love to get into the many ways that biologists have used to actually track birds on
their migrations. But honestly, we don't have time in this episode to go into any real detail on this
subtopic. I think it would be fun to make another standalone episode that deals specifically
with tracking birds. For now, just know that there's a handful of methods that have been
used, from simple leg bands to fancy GPS tracking. Recent advances in technology have truly
revolutionized the way scientists record the movements of birds. Here is one fun story,
though, related to tracking. In 2016, researchers in China placed small satellite tracking tags on a few
common kookos. They wanted to figure out where Chinese populations of this species spend the
non-breeding, i.e. winter season. School kids were tasked with naming the tagged birds. The two most
famous kookos were the ones with the most marvelously awesome names. Flappy McFlapperson and
Skybomb Bolt. The scientists and cheering public followed the progress of these birds in near
real time, thanks to the satellite tags, as they flew south to India, across the Indian
Ocean, and all the way down to southeastern Africa. You go, Flappy and Skybolt. Until this
study, nobody knew that these cuckoos flew all the way from China to Africa every year.
One final point about this story is that common cuckus are brood parasites. They're raised in
the nests of other bird species. This means that Flappy McFlapperson didn't have any parents to show her
the way to her non-breeding range. She had only her instincts for guidance on her first journey.
How crazy is that?
Okay, now let's talk about some important geographic features related to migration.
Let's consider those intrepid long-distance migrants.
Members of such species are often migrating in flocks, sometimes by the many thousands.
At times, in certain places, these birds come to, constant.
concentration points, as they fly along their migration routes, where they're funneled into
narrow places. All of these birds, of one species, or perhaps numerous species, are passing
through the same geographic bottleneck. Concentration points exist because some landscape
features and or weather patterns force birds to take particular roots, routes that offer the
least resistance. Famous examples of concentration points include Hawk Ridge in Minnesota, the
Straits of Gibraltar in Spain, and Centro de Veracruz in Mexico, home of the world-famous
river of raptors. Concentration points are pretty exciting places for us birders because they're
places we get to see tons of birds, possibly of numerous species, in a small geographic area
and over a short time period. So that's concentration points. Then we have staging areas.
These are places where birds stop on their long migrations, where they will hang out for a relatively
long period, sometimes for weeks.
Staging areas are where birds are fattening up on some local food resource before they hit
the skies for a long, arduous leg of their journey.
These areas are kind of like gas stations or fast food restaurants for birds, but instead
of just making a quick stop, they just keep ordering more greasy hamburgers for days
and days on end before they finally get back on the road.
During their spring migration northward along the Atlantic coast of the U.S., red knots stop
on beaches in New Jersey and Delaware to feast on the eggs of horseshoe crabs. During the
11 to 12 days a red knot will spend at this staging area, it will likely double its body weight
by eating the fat-rich eggs. In addition to staging areas, there are stopovers. Stopovers are
where birds will land for relatively short durations to rest and to do some feeding. Migrants might
spend one to a few days at a stopover. Recall the Swainson's Thrush I mentioned earlier, which makes
numerous hops during migrations, hanging out for a few days at each stopover.
Now, I know I made a point of talking about individual variation in migration paths earlier,
but it's still true that within a species, individual birds generally do follow fairly
predictable roots, and often multiple species will follow similar roots, passing through the same
geographic regions on their migrations. These multi-species shared roots are
what we call migration flyways. You've probably seen these depicted on maps. There are specific
flyways for various regions of the world. These are routes that multiple species take at an
intercontinental scale. Where I live in Oregon in the U.S., migrating birds are in the Pacific
America's flyway. This is one of the eight named flyways. Others include the Central
Asia and East Atlantic Flyways. Flyways are a classical way to envision the
migration roots of birds. As usual, reality is a bit messier than our tidy maps of avian flyways
suggest. But if you can ignore a bit of individual and interspecies variation, flyways are
still a meaningful way to think of migration. In contrast to the relatively narrow roots of
flyways, some species migrate in what is called broad front migration. This is where members of
a species just fan out across a continent as they're all heading south or north. They aren't
restricted to one narrow band or flyway.
Now, imagine you're a bird, and spring is approaching.
It's almost time to take off for your breeding site, thousands of miles away.
But how do you know when to take off?
To start your very long and perilous journey.
You can't read, not even at a third grade level, and you don't own a smartphone,
so looking at a calendar app isn't an option.
Well, you as a migratory bird do notice that you're feeling all fidgety and anxious this spring.
And now that you think about it, you feel this way every year.
But there's nothing in the environment that you're consciously aware of that makes you feel this way.
You just feel like you've got to move.
You got to get the heck out of here.
This overwhelming restlessness you feel in your bones has a name.
Zuckenruhe.
Zuggen what?
Zuckengruhe is the technical and very German word.
that I'm definitely mispronouncing for the increased anxious behavior that migratory birds show
when it's time for them to migrate. In many species, this behavior is strongest at night,
which is when these birds normally fly during migration.
Migratory birds are genetically programmed to show this behavior, because they have an internal
biological clock. This clock is driven by genetically determined hormonal changes that happen
on an annual cycle. The clock is calibrated by photo period.
When birds are able to experience normal patterns of natural daylight,
their clock is calibrated on a 12-month cycle.
Under experimental conditions, however,
the clock of a bird not allowed to experience its normal photo period
will drift a bit so that maybe its hormones end up on a 10-month cycle or a 14-month cycle.
With a normal photo period, the clock gets calibrated correctly and all as well.
So there is an instinct to migrate at a particular time of year,
an instinct which is driven by genes, and these genes have been honed by evolution.
Researchers have conducted many studies over decades to figure out all of this stuff,
and even more migration research has focused on what we're about to talk about,
orientation and navigation.
After a bird gives in to its inescapable impulse to migrate,
it still has the problem of figuring out where to go and how to get there.
To solve this problem of orientation, our bird needs three things, a compass, a map, and a way to tell time.
As for telling time, I already mentioned the biological clock that birds have for their annual cycles.
Birds also have an innate clock that tells them the time of day.
This too must be calibrated by the rising and setting of the sun.
Knowing the time allows birds to use other signals, such as the position of the sun and stars, to determine direction.
But many, if not most, birds appear to be born with the ability to sense direction.
Sensing direction by using the Earth's magnetic field is generally thought to be the most important orientation tool for birds.
This is their compass.
But there is plenty of evidence that at least some birds also use the sun and stars to determine direction in addition to the magnetic field.
So we have a way to tell time and a compass, but some sort of map is still needed for successful migration.
In some species, such as many geese and other waterfowl, juvenile birds in their first year follow adults to their non-breeding areas.
These young birds take note of landscape features such as rivers and coastlines so that they can make the journey on their own the next time.
They may also incorporate the patterns of constellations in the night sky.
They end up with a mental map of their migration route.
Many other bird species don't have the luxury of being guided by their parents on their first migration.
Instead, these species are actually born with the basic directions they need, hardwired into
their brains. Their instincts tell them which direction to go, when to go, and how long they
should fly before stopping. This is just amazing to me. Natural selection has programmed these
birds to fly, sometimes thousands of miles, to a place they've never been. Just like Flappy McFlapperson,
they end up where they need to be, or close enough to it, to successfully breed and survive.
Not surprisingly, though, there is still plenty of learning that takes place.
Young, inexperienced birds are more likely to get off course and end up in the wrong place.
Veteran migrators have developed much more detailed mental maps
and end up exactly where they need to be with much more regularity.
They integrate the magnetic field with visual landmarks
and possibly even smells and sounds to create an accurate map.
So much more could be said about how birds find their way around the world.
For now, though, let's move on to the physical challenges and changes that birds go through during migration.
For a small animal like a bird, undertaking these journeys is incredibly risky and energy demanding.
Migration takes a lot of energy because these animals are flapping their wings for many hours, sometimes days without stopping.
So in order to prepare for their migrations, birds need to store up a bunch of energy.
Fat is the best nutrient for energy storage.
For its weight, it has the most bang for the book.
Birds preparing for a long haul will gorge themselves on
fat-rich insects, mollusks, nuts, or berries.
This behavior of eating like crazy is called hyperphagia.
This is the same sort of thing animals like bears do before going into hibernation
and what humans do for no good reason during the holidays.
When birds are feeding and getting ready to migrate,
or when they're at staging areas,
their digestive systems grow dramatically
to allow them to eat enormous amounts of food.
They pack on lots of fat relatively quickly.
When it's time to fly and to migrate,
their digestive systems contract and shrivel up
since these organs would just be dead weight
while the bird is flying.
Conversely, their pectoral and other flight-related muscles
grow and their respiratory systems expand
to become really powerful and efficient.
Flying fast and furious over long distances would be hard enough,
but birds also have to deal with challenges along the way,
primarily wind and storms.
Flying into a headwind, wind that's coming at you head on,
is going to greatly increase the number of calories you need to burn per hour.
So birds prefer to have a tailwind,
and the timings and the paths of their migrations
often take advantage of tailwinds and mild weather.
Some types of birds tend to migrate during the day,
others do so at night.
Large soaring birds, like raptors, commonly migrate during the day
because their broad wings allow them to make use of thermals and updrafts to conserve energy.
Smaller birds can't really do that.
Smaller species often migrate at night so they can avoid aerial predators like falcons
and perhaps take advantage of cooler temperatures and calmer atmospheric conditions.
Migrating birds often become exhausted when they've been flying non-stop,
and even more so if they run into a storm or strong headwinds after a long flight.
These birds will sometimes fall out.
This is an actual technical term in an ornithology, fallout.
When birds hit bad weather after a long journey,
often after flying over the ocean or another large body of water,
they will abruptly come down to land to rest and recover.
Sometimes this happens all at once to thousands or even millions of birds
across multiple species.
Like the concentration points I mentioned earlier,
fallouts can be very exciting to bird watchers
because we can see lots of migrant birds all resting in the same area.
The migrations of birds connect all the planet's continents in a way that no other biological
process can match. Birds show us clearly how interconnected our world is and how important
it is that we protect natural habitats, not just in our own backyards, but everywhere.
My wife and I are so happy when the Swainson's Thrushes return to our yard every May.
their spiraling song.
Yep, that one is a defining sound of our verdant spring.
We love knowing that these thrushes are breeding in our forest
and that we can offer them sanctuary.
But those very same birds might fly all the way to Peru in autumn.
Their survival depends just as much on the preservation of their habitat in that country.
By understanding the migratory patterns and behaviors of birds,
we're better equipped to help them.
Bird migration is one of the great wonders of the natural world,
and we should do what we can to keep the flyways filled with rivers of migrating birds.
That is all for this episode.
Thanks so much for listening and learning with me today.
I really hope you picked up at least a few new and fun facts about migration.
With each episode, I hope to make the Science of Birds podcast better and better.
It will keep evolving.
I'd love to hear any thoughts or comments you have about,
the show. Just let me know by sending an email to Ivan at scienceofbirds.com.
And hey, if you love birds and want to learn more about their biology, please subscribe to the
podcast. You can also see the show notes for this episode, which is episode four, on the
Science of Birds website, scienceofbirds.com. On the website, you can make my day by subscribing to
our email newsletter. So check out Scienceofbirds.com. I'm Ivan Philipson, and I'll catch you next time.
Adios, friends.
Thank you.