Thanks to Curiosity Stream for supporting
PBS Digital Studios. Imagine an enormous rainforest teeming with
life: trees, insects, pretty little birds. Primates are climbing in the canopy, while
crocodiles and turtles swim in the rivers below. Beautiful, isn’t it? Now imagine this lush rainforest ... in the
Arctic. There was a time -- and not too long ago -- when
the world warmed more than any human has ever seen. So far. This ancient warming took place over the course
of just 200,000 years -- the blink of an eye in geologic time -- and it ended much like
it began: suddenly and mysteriously. It all started 56 million years ago, at the
very end of the Paleocene Epoch. Back then, life was still recovering from
the unpleasantness of the Cretaceous-Paleogene extinction event, which wiped out the non-avian
dinosaurs. And things were already warm by today’s
standards. There were no polar ice caps, which meant
sea levels were much higher. And the continents -- which were just beginning
to take a familiar shape -- were covered in habitats like temperate forests, and deserts,
and a belt of rainforests around the equator. But this environment was about to change. In fewer than 20 thousand years, the global
average temperature increased by 5 to 8 degrees Celsius. And the warming was greatest at higher latitudes. So, at the poles, temps on land reached an
average of 23 degrees, while the ocean waters got up to a balmy 20 degrees, This means you
could’ve gone for a comfy swim in the seas around Antarctica! This remarkable and sudden warming event is
known as the Paleocene-Eocene Thermal Maximum, or PETM, and it had a massive effect on
life on Earth. For one thing, when the PETM reached its peak,
rainforests had expanded much farther than they ever had before. Fossils from North America, Europe, and Asia
reveal habitats rich in plant life that today are associated with tropical rainforests
-- even though these forests were nowhere near the tropics. The fossilized fronds of palm trees have been
found as far north as Wyoming, for example. And some places within the Arctic Circle,
like Ellesmere Island in Canada, show evidence of ferns, redwoods, and gingkos. So. How was all of this -- any of this -- possible? Our best clues can be found in ancient sediments. Marine sediment samples from Maryland to Antarctica
show that, about 56 million years ago, there was a sudden spike in the amount of carbon
dioxide and other greenhouse gases in the oceans. And judging by the types of carbon found in
these sediments, the gases likely came from organic matter, like plants. See, plants, like most living things, prefer
to use the lighter and more common isotope of carbon, carbon-12, as opposed to heavier
isotopes, like carbon-13. So, this biogenic carbon -- which we’ve
talked about before -- has a different chemical signature than carbon that’s never been
part of a living organism. And, sediments that date to the start of the
PETM, show a large and sudden drop in the ratio of carbon-13, compared to carbon-12. This means that a bunch of biogenic carbon
must have suddenly been released into the atmosphere, in the form of carbon dioxide,
methane, and other gases. But, where did these gases come from? Well, one hypothesis is that there was a rash
of massive wildfires that unleashed tons of CO2 that had been locked up in plants. Another model proposes that giant seams of
coal were exposed to the heat of volcanic activity, which would have released the carbon
from fossilized plants. Or it could be that an otherwise mild warming
event triggered the release of greenhouse gases, by melting deposits of a compound known
as methane hydrate. Methane hydrate is similar to ice, but it
contains molecules of methane trapped by molecules of water. And hydrates are usually stable, as long as
they’re under a lot of pressure, like deep in the oceans, or if they’re kept cold,
like in permafrost -- the thick layer of frozen soil that forms in cold climates. But if these places warm up, the hydrates
melt, releasing bursts of methane, which is an even more potent greenhouse gas than CO2. And of course, the more warming that happens,
the more melting there is, which releases even more greenhouses gases, creating a classic
positive feedback loop. Now, no matter how it started, it’s worth
noting that, during the PETM, carbon was released into the atmosphere at only a fraction of
the rate at which it’s being emitted today. One study of marine sediments from the Arctic
showed that, at the peak of the PETM, as much as 1.7 billion metric tons of carbon were
released into the atmosphere every year, for at least 4,000 years. A similar study of sediments from New Jersey
put the figure at about 1.1 billion tons of carbon every year. Now, compare that to the amount of carbon
being released today. In 2014 alone, it was 9.8 billion metric tons
of carbon. So, 56 million years ago, carbon was being
released less quickly than it is now, but those emissions continued for thousands of
years. And it was more than enough to create a potent
greenhouse effect. With more carbon in the atmosphere than plants
could absorb, the planet started to change rapidly. In many places, the climate delivered a combination
of humidity and heat that allowed vast rainforests to flourish. And among the animals that thrived in these
warm forests were reptiles. Fossils of alligators, crocodiles, and turtles
can be found in nearly every fossil bed from the PETM -- even in the polar forests of Canada
and Greenland. And these lush forests were also where many
early mammal groups diversified -- including our every own lineage, the primates. In fact, the earliest true primates appear
in the fossil record just as the PETM was starting to take off, 56 million years ago. They adapted quickly to a world covered in trees, developing things like forward-facing eyes, fingernails instead of claws, and opposable
thumbs. These features gave primates such an edge,
that by 53 million years ago, they could be found across the northern hemisphere -- from
tiny Eosimias in China to Notharctus in Wyoming. But in the oceans, life in hothouse Earth
became much harder. In fact, in some places it was almost impossible. At the equator, ocean temperatures were unbearably
hot, sometimes reaching as high as 36 degrees, almost as hot as your average hot tub. This was probably too hot for many kinds of
plankton, which were -- and are -- the basis for most ocean food webs. But an even more devastating side effect of
high CO2 levels was ocean acidification. When ocean water absorbs CO2, it becomes more
acidic. And this in turn depletes the water’s concentration
of carbonates -- the compounds that many organisms use to build shells and other structures. And this is why one of the clearest effects
of the thermal maximum can still be found in core samples from the deep sea. Sediments that date back to before the warming
are typically pale in color, because they’re rich with the skeletons of deep sea foraminifera. Also known as forams, these are tiny protozoans
that build shells of calcium carbonate. And where forams were abundant, the chalky
fossils of their shells turned the ocean bed white. But when the oceans became more acidic, the
sediments turned dark. Because … most of the forams just disappeared. During the PETM, between 30 and 50 percent
of all foram species went extinct. The same phenomenon also stunted the growth
of hard corals, which need carbonates to build their skeletons, too. So, during the PETM and for millions of years
afterward, big, complex coral reefs all but disappeared from the fossil record. All told, the thermal maximum was a mixed bag
for life on Earth – proving to be an important period for us mammals, but a major loss for
some marine life. And, like all dramatic events, the PETM did
come to an end. Although, we’re not sure how, or
why. Over the course of the Eocene epoch, the climate
slowly began to cool. And although the temperature occasionally
spiked again, it never reached the extremes of the maximum. Temperatures kept dropping during the Eocene
-- so much so, in fact, that by the end of the epoch, 34 million years ago, polar ice
caps had begun to form. But, how did we get from rainforests near
the poles to ice caps? Well, the cause of the initial cooling that
actually stopped the PETM 53 million years ago remains a mystery. But something allowed that cooling to take
hold, and make the world even colder. And the answer here might have to do, again,
with plants. Arctic sediments that date back to the early Eocene
-- 49 million years ago -- have been found to contain huge swaths of fossilized aquatic
ferns known as Azolla. These plants thrived in the lush, warm Arctic. But as the environment changed, they died
off. And as they dropped to the seafloor, the thinking
goes, they took tons of carbon with them, which caused temperatures to drop even further. Despite how little we know about its end,
or its beginning, the Paleocene-Eocene Thermal Maximum shows us just how polarizing climate
change can be for life on Earth. For some organisms, like early primates, the
warming was a chance to develop new forms and spread to new locations. But for corals, forams, and other marine life,
such extreme heat spelled disaster. It gives us, in the midst of our own period
of warming, a view of how extreme the effects of climate change can be. And it allows us to make some pretty striking
comparisons. Remember when I said that, during the PETM,
the globe warmed more than humans had seen so far? Well, keep in mind that, in recent years,
the rate of annual carbon emissions have been more than five times greater than they were
at the peak of the PETM. As a result, our world is warming faster
than it did back in the Eocene. Just over the past hundred years, the average
global temperature has increased by about 0.7 degrees Celsius. But that’s just been over the past century. During the PETM, it took perhaps thousands
of years for temperatures to rise that much. So the PETM is the closest we can get to understanding
the effects of global warming today. And it has a lot to teach us about the extremes
that life experienced, on land and in the seas. Yes, rainforests full of primates and insects
and reptiles is beautiful. But I think you’ll agree with me that most
of us like them right where they are today. PBS Digital Studios is sponsored by Curiosity
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As a geology student whose thesis focused around the PETM, I'm glad to see some general education videos about this radical point in climatology in the Cenozoic. It is hugely important to understand this particular point in earth history in order to make educated guesses about how the extreme rate of carbon release beginning in the industrial age will impact the future of our progeny.