Thank you to FOREO for supporting PBS. In 2007, in a quarry just outside
a village in northeastern China, a farmer stumbled upon what seemed like
some kind of small dinosaur fossil. A museum bought the fossil from him, and in 2015,
scientists announced that this chance discovery was a dinosaur unlike any found before.
It was a pigeon-sized, feathered creature from the Late Jurassic Period, around 159
million years ago. And it seemed like a very close relative of the earliest birds,
which also got their start around this time. But it had one bizarre feature that had
never been seen before in any ancient bird relative, or in any other kind
of dinosaur: bat-like membraned wings! They named it Yi qi, which means
‘Strange Wing’ in Mandarin. Overnight, it showed us that there was
a lot more going on near the origin of birds than we had previously thought.
And its differences from birds actually makes the birds we know seem like
the weird ones in comparison.
'Cause if we take a step back, the discovery of
Yi qi forces us to ask an important question: from an evolutionary perspective,
who really has the stranger wings?
When we think of wings, many of us might picture feathers, probably
because birds are so familiar to us. We're just used to feathered wings being
the default for airborne dinosaurs. And for decades, the fossil record seemed to
back this up, with paleontologists finding feathered dinosaurs in China and elsewhere.
And though we knew we didn't have the full picture, the evolution of feathered wings in
theropod dinosaurs, eventually leading to flight, was thought to have happened in a relatively
linear process of gradual refinement… …From poor flyers at first like Anchiornis,
to Archaeopteryx which could flap its wings enough to fly in short bursts, to
the birds that fill the skies today. And there was no evidence to suggest otherwise,
no reason to think that other bird relatives might have taken an evolutionary detour and developed
totally different kinds of wings altogether. But in the early 2000s, a couple
of interesting members of one particular dinosaur family were described.
The first, in 2002, was the sparrow-sized juvenile specimen of Scansoriopteryx,
which is also called Epidendrosaurus, depending on which researchers you ask.
It was followed by the magpie-sized Epidexipteryx in 2008.
And, based on some of the unique skeletal traits of these two species,
researchers hypothesized that this family, the scansoriopterygids, were small dinosaurs
with an arboreal, or tree-climbing, lifestyle. These traits included their long arms,
an extended digit on each hand, and feet that seemed adapted for perching.
So for over a decade, this family, known only from a handful of other small fossils
from the Mid to Late Jurassic Period of China, was just considered a strange group of dinosaurs…
…One that was closely related to the lineage that gave rise to birds and that
had adapted to life in the trees. Now, this was already plenty fascinating
- no other non-avian dinosaurs are thought to have been so arboreal.
But the discovery of Yi qi revealed that there was even more to this
group than we originally thought.
The incredible level of preservation of this
specimen meant that some soft tissue elements were still visible – including clear
evidence of a membraned wing attached to a rod-like extended wrist
bone that gave it structural support. It suggested that Yi qi, and probably some of
the other members of its family, were not just climbing, but also taking to the air!
And other scansoriopterygids that were found later provided more evidence of this.
Like Ambopteryx, which was also found by a farmer in northeastern China and described in 2019.
It’s a close relative of Yi qi that also has evidence of a membraned wing attached
to the same extended wrist bone. So researchers proposed that these
dinosaurs represent a previously unknown independent experiment in dinosaur flight.
Maybe even one of many experiments near the origin of birds - the group that usually comes to
mind when we think of ‘winged, flying dinosaurs’. Though, it’s hard to tell from fossils
alone whether they were capable of powered flight – like birds and bats –
or gliding flight like flying squirrels, though gliding seems much more likely.
One study from 2020 that modeled their flying abilities based on their wing
structure even found that they probably couldn’t do much more than very clumsy,
short-distance gliding between branches. They argued that Yi qi, Ambopteryx, and the rest
of their family were not just an experiment in dinosaur flight, but a failed experiment.
And that might be why all the species found to date are from roughly the same time and place
in the Late Jurassic: the experiment hit a dead end due to competition with other groups, like
the ancestors and closest relatives of birds. It was in the Late Jurassic, after all, that
feathered wings also first appeared and gradually became more refined for flight over time.
Eventually, this gave feather-winged dinosaurs flying skills that were much more
impressive than anything the membrane-winged Yi qi and its relatives had managed.
Now, while the scansoriopterygids had both feathers and wings, they didn’t have feathered
wings, and they certainly didn't have the best of both worlds when it came to flight.
Because their feathers, preserved in some specimens like Yi qi, were
simple, stiff, and paintbrush-like. They were probably used for thermal
insulation and for display, as they were in many other non-avian dinosaurs.
In contrast, the flight feathers of birds that cover their wings have a totally
different and more complex structure.
And because feathered wings are so successful
today, we take them for granted, and think of membrane-winged dinosaurs as strange and unusual.
But if we take a broader view, maybe the way we think about Yi qi and its
relatives is totally backwards. Membraned wings aren't strange at all, really.
They’ve convergently evolved many times across the animal kingdom, from pterosaurs
- the sister group of dinosaurs - to mammals like bats and flying squirrels.
They show up so often for a simple reason, too - their simplicity.
Membraned wings don't require nearly as much evolutionary innovation.
The right mutations come together for an area of skin to grow more than usual,
and for the arms to change to support it, and boom, you've got yourself a membraned wing.
And these membranes often enable gliding flight, and in some cases even powered flight, to
quickly evolve in previously flightless groups. So, is it really surprising that
some dinos, like so many others, went in this direction too, experimenting
with gliding flight via a membraned wing? The fact that we saw them as strange
is more like a testament to the success of feathered wings instead.
But birds are not normal, folks. Flight feathers are just about the
weirdest and most complex things to ever sprout from vertebrate skin.
And, as far as we know, in the entire history of life on Earth, using feathered
wings as a means of flight evolved only in birds and their closest dinosaur relatives.
And if birds were to go extinct, the skies of planet Earth would be feather-free
and might remain that way forever. But if every animal with a membraned wing
went extinct today, on the other hand, you can comfortably bet that very similar
structures would show up again before too long. They just don't require nearly
as much evolutionary innovation. So, from a certain point of view, Yi
qi – our so-called ‘Strange Wing’ – and the other scansoriopterygids
weren't so strange after all. They were just one of the many diverse groups that
independently experimented with this same, simple approach to becoming at least kinda airborne.
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me to read, like this one from Kassy W. What do you call crooners
on parasails? Dino-soars! I don't get it... What? Crooners? So they're saying they're old? Well, that's rude. I like crooners! And as always thanks for joining me
in the Adam Lowe studio. Subscribe at youtube.com/eons for more ancient adventures. Epidexipteryx... Epidexipteryx. ...magpie-sized Epidexipteryx
[said with uncertainty] [laughs] Believe in yourself! Don't get scared and stop halfway through the
sentence, you're gonna say the WHOLE sentence... blind confidence... It was followed by the
magpie-sized Epide-bic-ter... Aaahhh! It was followed by the
magpie-sized Epidexipteryx in 2008. Huh? [off-screen] I think that was it. [sighs in relief]
Oh, the outtakes you'll have for this one!
The science is in
The eons of time are mind bending. Pigeons no less