The Science of Birds - Woodpeckers
Episode Date: October 29, 2020SummaryLearn about the amazing birds in the family Picidae—the woodpeckers. These charismatic birds have a suite of adaptations that make them excellent at the job of excavating wood. In this episo...de, we first summarize the key features of woodpeckers.Then we’ll look at the evolution and modern-day diversity of the family.We discuss many of the special adaptations of woodpeckers, which they use as they go about their day, foraging.How woodpeckers breed and communicate and a bit about their conservation status round out the episode.Links to Some Things Mentioned in this EpisodeDean Hale Woodpecker Festival in Sisters, Oregon (USA)Link to this episode on the Science of Birds websiteSupport the show
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You can probably recognize a woodpecker as soon as you see one.
Unless it's flying, the bird is probably sitting upright, clinging to the side of a tree trunk.
Maybe it's hitching itself upward in short little bursts.
Maybe it's hammering its bill rapidly against the tree.
You may not know which species you're looking at, but you know what type of bird it is.
You've got yourself a woodpecker.
The body plan of a typical woodpecker is the same all around the world, across about 200,000.
species. Sure, some have jazier crests on their heads and some are more colorful, but pretty
much all of them have the machinery needed for the special task of hacking into wood with their
beaks. This might involve just methodically flicking flakes of bark off a trunk, or it might involve
obliterating large sections of a decaying tree. How do you feel when you spot a woodpecker?
I hope the answer is super stoked. That's certainly how I feel. In my experience, as a birding guide,
I'd say people are usually pretty happy to see woodpeckers.
These birds are charismatic and really fun to watch.
A few hours from where I live in Oregon,
there is a sort of mini biodiversity hotspot for woodpeckers.
East of the Cascades Range,
in a narrow north-south band of ponderosa pine forest,
11 woodpecker species regularly breed.
My favorite is probably the white-headed woodpecker.
It's uncommon enough that I don't always find one when I'm out that way.
The little town of Sisters, Oregon, sits right at the heart of this woodpecker vortex.
There's actually an annual woodpecker festival there, with guided birding excursions to find all the species.
I would happily spend a day or two or three searching for every one of those 11 woodpecker species.
Maybe that's right up your alley, too.
Or maybe not.
That's okay.
But I do hope you want to learn a lot about woodpeckers, because that, my friend, is what you're about to do.
Hello and welcome.
This is the Science of Birds.
I am your host, Ivan Philipson.
The Science of Birds podcast is a lighthearted, guided exploration of bird biology for lifelong learners.
In this episode, we're focusing on one bird family, pickety.
If there was a drinking game for this episode where you had to take a shot every time I say woodpecker,
well, you'd be passed out drunk in a matter of minutes.
Please don't do that.
Instead, stay alert and join me as we get this party started.
Several outstanding features make woodpeckers so easy to tell apart from other birds.
Let's quickly go over these features now and then I'll get into more detail on some of them later.
So we're starting with an overview.
The first feature is the fact that, well, woodpeckers peck wood.
The name says it all.
In Spanish, a woodpecker is called a pacharo carpintero, a carpenter bird.
I imagine that in most languages, the name for these birds captures the wood-destroying
aspect of their behavior.
Woodpeckers have a straight, chisel-shaped bill.
This is a finely honed tool for excavating wood.
What they're looking for beneath the surface are insects to eat.
A long thin tongue helps them snatch bugs out of little crevices and tunnels they expose in rotting wood.
The posture and movements of woodpeckers are distinct.
They tend to hitch themselves up tree trunks while in an upright posture.
These movements often look herky jerky.
And when woodpeckers fly, many of them have a bounding or undulating flight path,
where they rise a little as they flap their wings and fall.
a little between bursts of flapping.
Stiff tail feathers and strong feet allow a woodpecker to brace itself against a tree while
whacking at the wood.
Besides digging for insects to eat, woodpeckers also use their bills for communication and for
excavating their nests.
They communicate with each other by drumming against wood to make a loud sound.
Drumming is one of their unique features.
And all woodpeckers are cavity nesters.
Most of them create their nests by chipping out a deep hole.
hole in wood. Many woodpecker species have bold black and white coloration on just the head or
over most of the body. Splashes of red and yellow are also common. And quite a few species have
greenish wings. Despite these general patterns, there's plenty of color variation across this
diverse bird family. There's no one pattern seen in all woodpeckers. So these are the key
features of woodpeckers. If this was a fourth grade science report and I was
reading it in front of the class, I would end right there and then flash my teacher a toothy smile,
hoping she was impressed by all the big words I used. But this ain't elementary school, dang it.
This is the Science of Birds podcast, and we have much to discuss regarding our Pajaro Carpintero friends.
Millions of years ago, the ancestor of all woodpeckers figured out how to access
a rich and mostly untapped resource, juicy and nutritious bugs, burrowing around in wood.
Natural selection then favored individual birds that were better at digging into wood and
capturing prey. And so the woodpecker was born and the world has never been the same.
Today, there is a boatload of woodpecker species. They've been successful in their unique
lifestyle, their niche. They have adaptations that make them really good at what they do. Most of
the salient features of woodpeckers that we just talked about relate to their special
adaptations. But these traits didn't appear all at once in prehistoric woodpeckers. It took a long
time. A study published in 2012 offers a model for the stepwise evolution of traits
that allowed woodpeckers to become more and more specialized. By analyzing anatomical and
behavioral data from across most of the modern woodpecker lineages, the researchers in that study came up
with this progression.
The earliest woodpeckers could drill into wood to find bugs,
but they didn't have strong enough skulls to excavate their own nests,
and they couldn't climb up tree trunks.
In the next step, they developed reinforced, tougher skulls and bills.
That allowed them to hollow out their nests.
In the last steps, their toes moved into the modern arrangement,
and their tail feathers got stiffer.
With strong, grippy feet and a rigid tail,
they developed a support structure that allows for tree trunk climbing shenanigans.
Now let's rewind to those very first ancestral woodpeckers.
Where did they live?
The actual geographic origin of woodpeckers is still a mystery.
Scientists have been using fossils, comparative anatomy, geographic distribution,
and DNA sequences to figure out where and when woodpeckers first hopped onto the scene.
And I love this.
I love it that a bunch of people,
are out there putting their blood, sweat, and tears into figuring out where woodpeckers came
from. This fills my heart with joy. Anyway, the reason we can't say for sure where these birds
originated is because different lines of evidence support wildly different scenarios. For example,
if you look at the high species diversity of the relatively primitive pickulates in South
America, that would suggest that the woodpecker family got its start on that continent. But there
are a few older but less diverse lineages in the old world, and that's also where the oldest
woodpecker fossils have been found. The most likely origin story for woodpeckers is that they
first evolved in the tropics of Eurasia, about 45 million years ago. Around that time,
the ancestor of all woodpeckers became a distinct creature, splitting off from the lineage that
became the modern honeyguides. Honeyguides live in Africa and Southeast Asia. They're the
closest living relatives of woodpeckers. The oldest woodpecker fossil we've discovered
is a leg bone from Germany. It's from a bird that lived about 25 million years ago during
the late oligocene epoch. So this is one of those fossils that supports the Eurasian origin
of woodpeckers. The earliest evidence of woodpeckers from the western hemisphere is a feather
suspended in amber from the Dominican Republic in the Caribbean. That fossil is from about
23 million years ago. Woodpecker evolution and species diversification really got cooking
starting around 14 million years ago. They spread around the world and evolved into hundreds
of species. They came into their own, occupying their specialized niche as arboreal, forest
dwelling, tree drilling, bug-eating machines. The Woodpecker family, Piccadies,
is diverse. Depending on the list you look at, there are something like 234 to 254 species in this
family. Not too shabby. The name of the family comes from the Latin word pickus, which means
woodpecker. Fair enough. And pickus probably came from a related Latin word picko, meaning to
strike or peck. This is just stuff I dug up on the worldwide web and found interesting. If you're
a scholar of Latin etymology, please email me and tell me how very wrong I am.
The family Piccadie has three, or quite possibly four, distinct sub-families.
The two species of Rinex, that's W-R-Y, Rinex, those make up one sub-family.
Then there are about 30 species of piculets.
From their name, you can guess that piculets are tiny little nugget-like woodpeckers.
They have stubby bills and short tails.
The so-called true woodpeckers make up the last and largest of the sub-families.
There are about 200 species.
Genetic data indicates that one piculet species, the antelian picculate, is divergent enough
that it probably should be assigned to its own sub-family within the woodpecker family.
This unique bird lives on the island of Hispaniola in the Caribbean.
The smallest woodpecker in the world might be the same.
the bar-breasted picculet that lives in the Amazon Basin of South America.
This little bird is only three inches long, which is 7.5 centimeters.
That's not much larger than some hummingbirds.
At the other extreme is the great slaty woodpecker.
This beefy beast is up to 20 inches long, 50 centimeters, and can weigh about 1.25 pounds or
560 grams.
Doesn't sound very heavy, maybe, but hey, it's a bird.
This long-necked, long-billed woodpecker is almost entirely gray-colored.
It lives in Southeast Asia.
Speaking of necks, in my neck of the woods, we have the palliated woodpecker.
It's the largest member of the Pickety family in North America.
It's about the size of your standard-issue crow.
I love hearing and seeing these big black, white, and red birds in the forest.
They kind of remind me of something prehistoric, like a pterodactyl.
The 240 or so woodpecker species are mostly creatures of the forest, but members of this group
can be found across a wide variety of habitats. Some live in open woodlands or savannas, others
live in grasslands or deserts. A handful of species have even evolved to have a terrestrial
lifestyle, foraging in the dirt or grass rather than on trees. These species tend to live in
open areas with few trees. A few, like the ground woodpecker of Southern Africa and the
Campo Flickr of South America, dig their nest cavities in the ground. The ancestors of these birds
were tree dwellers, so this earthbound existence evolved secondarily. Fascinating. Woodpeckers live
in all these arboreal and terrestrial habitats across most, but not all of the world. They are
conspicuously absent from Madagascar, New Guinea, Australia, and New Zealand.
They aren't on Antarctica either, but that goes almost without saying.
This biogeographic pattern is a little surprising. I mean, woodpeckers managed to get
everywhere else, right? One explanation is that maybe woodpeckers are very reluctant to fly
long distances over water, over stretches of open sea. Are you a woodpecker that wants to get to
Madagascar from mainland Africa?
Oops, you need to fly over water, sorry.
Are you a Eurasian green woodpecker in England?
Forget about starting a new life in Ireland because, you guessed it, water.
Like so many other animals, woodpeckers have been prevented from dispersing into New Guinea in Australia
by a stretch of open water east of Bali and Borneo.
This marks what we call Wallace's line.
This biogeographic dividing line, or barrier, was first described by Alfred
Russell Wallace, the 19th century naturalist who discovered natural selection at the same
time Darwin did. Animals and plants on either side of the line are very different. Only three
woodpecker species live east of it. Maybe I'll do a whole podcast episode on Wallace's
line at some point. It's a fascinating topic. The hypothesis that dispersal has been restricted
by oceanic barriers explains some geographic patterns in woodpeckers, but certainly not all of them.
It's not perfect.
But now let's look at the places where woodpeckers have been able to get to.
Here's a quick breakdown of their diversity, continent by continent.
We have 60 species here in North America.
The most commonly observed are the Downey woodpecker, northern flicker, and red-bellied woodpecker.
Downies are our smallest woodpeckers and their regular visitors to backyard feeders.
South America has the highest diversity of any continent.
with between 85 and 92 species.
The green-barred woodpecker, red-crowned woodpecker,
and Campo Flickr are the most common species there.
In Europe, you're most likely to see Great Spotted, Green, and Black woodpeckers.
There are nine other species living on that continent, so a total of 12.
Only four are found in the United Kingdom.
Interestingly, the African continent has just 33 woodpecker species,
The most widespread and commonly seen is the cardinal woodpecker.
Woodpeckers in Asia are almost as diverse as they are in South America.
There are between 75 and 80 species in Asia.
Of course, the birds of Europe and Asia have some overlap,
so it's not a shock to find that the great spotted woodpecker
is the most commonly recorded species on both continents.
The gray-headed and white-backed woodpeckers
are the next most common species in Asia.
The sun rises over a golden forest in eastern North America.
It's autumn.
The morning light rouses a red-bellied woodpecker tucked in its roosting cavity.
This cozy wooden cave was carved by the bird into the trunk of a dead tree.
After some stretching, the woodpecker pops its head out of the entrance hole to have a look around.
The coast is clear, so it flies off into the forest.
Our woodpecker has a bright red crown and nape and a cream-colored body.
Its wings are black with bold white barring.
The belly has only a faint, almost imperceptible pink wash,
so maybe red-bellied woodpecker wasn't the best name for this species.
This bird will spend the daylight hours as it does almost every day of its life,
searching for food.
It will be continuously active as it forages in the forest.
Landing on the trunk of a big oak tree, the woodpecker clings to the vertical bark surface.
Most birds can't do this so easily, if at all, but woodpeckers have specialized feet and tail feathers
allowing them to rest comfortably on vertical trunks.
Strong feet with sharp claws act like grappling hooks, anchoring the bird to the bark.
Two of the toes face forward and two faced backward.
The technical word for this arrangement is zygodactyl.
This comes from ancient Greek, meaning paired fingers or paired toes.
Think about teradactyl, a word I used earlier.
That means wing finger.
Zygodactyl feet aren't unique to woodpeckers.
Owls and trogons have them too.
But your typical perching birds have three toes forward and one toe backward.
That's called the anisadactal arrangement.
So our red-bellied woodpecker is clinging to the bark with its zygodactyl.
fractal feet. To maintain its perky upright posture, the bird's tail also plays an important
role. Among birds, woodpeckers have unique tail feathers that are extra stiff. Pressed and
spread against the tree trunk, the tail feathers provide a third sturdy point of contact,
forming a sort of tripod. Woodpeckers need to brace themselves this way to be efficient in their
wood chiseling frenzy. When the woodpecker is ready to move up the tree trunk, it does a quick
little jump. It jumps up a short distance and grabs on again with its feet. These little jumps
give the woodpecker's movements a staccato, stop-motion look when they are hitching themselves
up a tree. I love watching woodpeckers moving up a trunk. And they crack me up when they
scoot around to the far side of the tree when they know they're being watched. Cheeky little
buggers. Not all members of the woodpecker family, Piccody, have tails that work this way. I mentioned
that the piculets have stubby tail feathers.
Piculets belong to their own subfamily,
which is relatively primitive compared to the true woodpeckers.
With their short tails,
piculets aren't as good at bracing themselves,
and so they spend more time on horizontal branches.
Returning to the red-bellied woodpecker we've been following,
it's now actively looking for prey.
It's looking for insects and spiders among crevices in the bark,
and it's also listening.
Insects like wood-boring beetles and their
larvae make sounds that the woodpecker can hear. Reaching a large dead branch, our woodpecker
hears some activity inside. It braces itself, then begins pecking at the rotting wood. Soon it's
excavating a sizable hole in the wood and the chips are flying everywhere. Here's what that
sounds like. The red-bellied woodpecker has a chisel-shaped bill, which is typically
for members of the family pickety. The bill is straight and has a slightly rounded off or
squared tip, making it less likely to be damaged during pecking. As in other birds, the outer layer
of the bill is made of keratin. This is the same protein, more or less, that forms your hair and
fingernails. The regular pecking action of the bird helps to automatically sharpen the bill's
keratin sheath. Once our intrepid woodpecker breaches the insect tunnels in the rotting wood, it uses its
long, sticky tongue to catch its prey. A red-bellied woodpecker tongue can extend about three
times the length of the bird's bill. Long tongues like this are the norm for woodpeckers,
so chameleons and ant-eaters aren't the only animals with crazy long tongues. But where does this
tongue go when the woodpecker isn't using it? It retracts as part of an anatomical structure
called the hyoid apparatus.
This structure includes the tongue,
the hyoid bones,
muscles, and connective tissues.
The hyoid apparatus,
including the tongue,
wraps all the way around the back
of the woodpecker's skull.
Imagine your tongue
pulling back into your mouth,
then behind your head,
and then down over your forehead
and into your eye socket.
That's sort of what happens in woodpeckers.
Crazy, huh?
Hummingbirds, which we talked about in episode eight,
also have absurdly long tongues and a hyoid apparatus that wraps around the skull.
Now, if I smashed my face into an oak tree repeatedly, like a woodpecker,
I wouldn't be feeling very good, right?
This blunt force trauma would give me some major brain damage at the least,
and I might even die.
In that case, you might expect the quality of these podcast episodes to decrease a tad.
How the heck do woodpeckers happily whack away at wood
without any injuries. This is one of the most amazing things about these birds.
Our woodpecker friend has several adaptations that keep it from knocking itself silly when
excavating or drumming on wood. Without these adaptations, it would be at serious risk of getting
concussions. A concussion is a brain injury caused by a blow to the head. The hyoid apparatus
is one of these adaptations. Tension in the hyoid apparatus cushions the woodpecker's skull
and diverts vibrations from impacts away from the skull.
Another thing that prevents concussions is the small brain size of woodpeckers.
Smaller brain masses are less at the mercy of damaging force.
Now, it's not that woodpeckers have exceptionally small brains.
They actually have larger than expected brain sizes given their body sizes when compared to most
other birds.
But birds are just small animals, so their brains have small masses in general.
A woodpecker's skull is reinforced in front and back to withstand repeated blows,
and its brain is oriented inside the skull so that there's a large surface area to absorb any shock.
Also, the lower part of the bill, the mandible, tends to strike the wood surface first,
and this allows the shock to be absorbed by the mandible itself instead of the cranium.
In fact, force tends to be distributed throughout the bird's body instead of being concentrated in the skull.
And lastly, compression provided by the tongue allows woodpeckers to maintain blood, volume, and pressure in their heads.
This extra layer of protection acts sort of like blood bubble wrap to protect the brain.
Some head-banging mammals like male big horn sheep have similar adaptations to avoid concussions.
Biologists have studied woodpeckers and these mammals to figure out how to minimize concussions in football players.
Another occupational hazard for woodpeckers is dealing with sawdust and woodchips.
They need to protect their eyes and noses from these particles.
Every time a woodpecker strikes wood, it closes its third eyelid, the nictitating membrane.
This shields the eye from flying chips.
We talked about nictitating membranes in episode 7, which is all about vision and birds.
And many woodpeckers have narrow nostrils and or protective feathers called nasal tufts,
to keep woody debris from being snorted.
When you consider all of these adaptations we've been talking about,
you can really appreciate how natural selection has shaped these wonderful birds.
They are, as I said, really good at what they do.
The red-bellied woodpecker we've been following is no exception.
This species is a fine example of a typical species in the subfamily of true woodpeckers.
It uses its woodpecking superpowers to find and eat lots of bugs in wood.
but its diet is actually much more varied.
Depending on the time of year and on what food is available in the area,
red-bellied woodpeckers eat all sorts of stuff.
More than half of their food can come from plants.
Fruit and nuts like acorns and pecans are at the top of the list.
Besides beetles, they eat ants, grasshoppers, caterpillars,
and other miscellaneous invertebrates.
You might be surprised and perhaps a little horrified
to know that this bird also eats lizards,
frogs, and nestling birds of many kinds. Yeah, that's right. Baby birds. Bummer, but so it goes in nature.
This sort of menu isn't unique to the red-vellied woodpecker. The majority of woodpeckers are similarly omnivorous.
Take the great spotted woodpecker, for example. This species, which I mentioned is common in Europe and Asia,
has a diverse diet. It eats berries, nuts, tree sap, fruit, insects, spiders, mussels,
carrion, human food scraps, bird eggs, and, yes, baby birds.
And speaking of tree sap, we have some woodpecker species that specialize in eating this sugar-rich
liquid. The four sap-sucker species in North America all belong to the genus spherapicus.
That's a good one for the next fourth grade spelling bee.
Sph. F-incorrect.
These sap suckers drill shallow wells into the vascular tissue of living trees.
They lap up the sap that oozes out with their brushy tongues.
They also eat insects that show up to drink the sap.
Many other woodpeckers will eat tree sap,
but the sap suckers have taken this to a whole new level.
Drumming in woodpeckers is a different level.
distinct behavior. It's quite different from what they do when they're foraging for insects in
wood. It sounds different and has a totally different function. Here's a woodpecker
foraging.
Just kind of sounds like a sporadic tap. Just kind of sounds like a sporadic tap.
right? Now here's a woodpecker drumming.
Much different, wouldn't you say? Drumming is a form of communication,
because woodpeckers don't have the fancy vocal abilities of perching birds or other skilled
crooners, they can't use songs to attract mates or intimidate their
rivals. Instead, they've repurposed their wood chiseling skills to make a sound that
accomplishes these same tasks. While drumming, a woodpecker can strike wood more than 20 times in a
second. Try tapping your finger that fast. I don't know about you, but I sure can't do that. I don't
think anybody can. Most, if not all, woodpeckers use drumming to communicate. Males and females
both drum, and this behavior is seasonal, often being limited to the breeding season.
make the loudest possible drumming sound, a woodpecker will try to find a nice hollow branch
or tree trunk. This maximizes the resonance so that the sound will carry a long way. And some
clever woodpeckers have figured out that human structures make awesome drums. Have you ever had a
woodpecker jackhammering away on your stovepipe or rain gutter? It's super loud. This makes some
people mad, but I just think it's funny. It's not so easy to tell woodpecker species apart by their
drumming sounds alone. Drumming isn't as useful as songs to us birders, but there are subtle
differences in the rates of drumming that a skilled listener might be able to detect. Woodpeckers
can and do make vocal sounds, even if they can't sing complex songs. They have calls to keep in
contact with mates, to express alarm, and to threaten their enemies. Here's a call, for example,
from a downy woodpecker.
And here's a call from a great spotted woodpecker.
Let's talk about breeding in woodpeckers.
Most species are monogamous and have long-term pair bonds,
but some will pair up for a single season and then go their separate ways.
There are some interesting exceptions to the simple monogamy situation,
such as the cooperative breeding of red cockated woodpeckers and acorn woodpeckers.
These situations are fascinating and complex,
so I'll come back to them in a later podcast episode.
All woodpeckers nest in cavities.
Most excavate their own nests,
but some species, like the Eurasian Ryeck,
aren't able to do that themselves.
Ryecks use either natural cavity,
or those made by other woodpeckers.
And pickulates tend to dig out their nests in soft decaying wood.
These little dudes aren't powerful enough to make cavities in hard or living wood.
Nest cavities don't need to be in wood necessarily.
Some species routinely dig nests in termite mounds or ant nests.
For example, the Rufus Woodpecker in southern and southeastern Asia
often excavates its nest in an active nest of tree-dwelling ants.
I already mentioned that a few woodpecker species will nest in holes in the ground.
This is useful where trees are scarce.
The desert southwest of North America is one such place.
But there are some massive tree-like cactuses such as the famous saguaro.
The Gila woodpecker and the gilded flicker both carve their nests into the wet flesh of these giant cactuses.
Woodpecker eggs are white, just like the eggs of most other cavity nesting birds.
When your eggs are hidden in a dark place, there's no need for them to have pretty colors or camouflage.
The male woodpecker usually sits on the eggs at night, alternating shifts with the female.
Baby woodpeckers are born featherless and helpless.
We call this type of baby bird altricial.
The alternative is precocial, where the newly hatched bird is ready to rock with open eyes, functioning legs, and a body covered in warm fuzz.
Both woodpecker parents take care of their helpless babies.
the adults return to the nests to regurgitate yummy insects for the nestlings.
After about 20 to 30 days, the young woodpeckers are ready to leave the nest.
Woodpeckers deserve some major appreciation,
not just because they're funny and charming and beautiful,
and not just because they eat insects that might otherwise be harmful to forests.
We need to thank woodpeckers for their important roles as ecosystem engineering.
You see, by going about their normal business, woodpeckers unwittingly make changes to their
habitats. Some of those changes end up benefiting many other species. For example, there was a study
published in 2004 on cavity nesting animals in British Columbia, Canada. Over eight years,
the researchers collected data from 1,692 cavity nests of birds and mammals in a coniferous forest
ecosystem. It turned out that the northern flicker was the most important of the primary
cavity excavators. These woodpeckers, the flickers, carved nests into aspen trees, and their
nests were used secondarily by a whole menagerie of critters. Birds that used flicker nests
included buffalo head ducks, American kestrels, northern saw-wet owls, and mountain bluebirds.
But some mammals also made themselves at home in old flicker nests. These include
wood rats, mice, weasels, and squirrels. Sometimes, sadly, flickers get forcefully evicted from
their nests by other animals. How rude. The northern flickers in that 2004 study were
ecosystem engineers that created cavities in the forest. Cavities are a limited and valuable
resource. Several other species are also primary excavators in that ecosystem, including
pilliated woodpeckers, hairy woodpeckers, and red-naped sap suckers.
Without woodpeckers, nest cavities would be in short supply.
Another way that woodpeckers benefit their ecosystems is that they help along the process of breaking down dead wood into soil.
When a tree dies, bark beetles, woodbore beetles, and other insects arrive to eat the wood.
They bring with them wood digesting fungi.
Woodpeckers swoop in, tear open the wood, and eat the insects.
By exposing the wood, the birds increase access for even more insects.
fungi. This creates a sort of feedback loop, and eventually the tree gets recycled into organic
soil. This soil will nurture the next generation of trees, insects, and woodpeckers.
Out of approximately 240 woodpecker species across the planet, 39 are known to be threatened.
The International Union for the Conservation of Nature lists 39 woodpecker species.
as either near-threatened, vulnerable, endangered, or critically endangered.
Woodpeckers are, by and large, animals of the forest,
and forests worldwide are being destroyed at alarming rates.
So it's likely that many more woodpeckers will be pushed towards extinction
if we don't protect these habitats.
A global analysis published in 2018 indicated that the region with the highest woodpecker diversity
is Southeast Asia, where human modification and desks of the United States,
destruction of habitat is rampant. The 39 species that I just mentioned did not include two that are
on the IUCN Red List as critically endangered, the ivory-billed woodpecker and the Imperial
woodpecker. These birds are most likely already extinct, gone from the world. There's a tiny
bit of hope that they are still hanging on somewhere out there, but despite multiple
scientific expeditions to find them, no one has seen either species for decades. The
ivory-billed woodpecker lived in
primeval swamps of the American
Southeast. Its close relative
the imperial woodpecker lived
in pine forests in the mountains of
Western Mexico. These were the
two largest woodpecker species in the
world. Human caused devastation
of their forest habitats
has driven them to extinction.
This is really sad, don't you think?
I hope we can channel our
sadness into positive motivation
to do what we can to prevent any more
woodpeckers from disappearing. Like
so many other birds they need our help.
These lovely, brightly patterned, woodpecking, wood-wrecking birds make the world a better place.
They're fun to watch, they're biologically fascinating, and they maintain the health of the
ecosystems where they live.
We come now to the end.
I think I said the word woodpecker about 169 times.
I hope that you picked up at least a few new fun facts.
about these excellent birds, and I'm honored that you took the time to listen to this episode.
If you enjoy the episode and you're loving this podcast, please leave a five-star review
on Apple Podcasts or Podchaser. A good review is so, so helpful for helping me connect with more
people like you. I want to continually improve the Science of Birds podcast, so I'd love to hear
your thoughts or any comments you have about the show. Let me know by sending an email to
Ivan at
Scienceofbirds.com
And if you love birds
and want to keep learning
about their fascinating biology
please subscribe to the podcast.
You can do that on
Apple Podcasts, Spotify,
Google Podcasts,
and pretty much
any of the podcast apps out there.
You can see the show notes
for this episode,
which is episode 11,
on the Science of Birds website,
scienceofbirds.com.
I'm Ivan Philipson
and I'll catch you next time.
Cheers.