The Ancients - The First Life on Earth
Episode Date: January 1, 2026Today we’re going back to the beginning – no Romans, Celts, Egyptians or Macedonians in sight. Billions of years of prehistory as we look at the emergence of life on Earth. From the rise of the ea...rliest microscopic membranes to the arrival of the dinosaurs.Tristan Hughes is joined by Henry Gee to journey through several billion years of history; from the rise of the earliest microscopic membranes to the arrival of the dinosaurs.MORERise of Humans with Henry GeeListen on AppleListen on SpotifyJurassic AmericaListen on AppleListen on SpotifyPresented by Tristan Hughes. Audio editor is Aidan Lonergan, the producer is Joseph Knight. The senior producer is Anne-Marie Luff.All music courtesy of Epidemic SoundsThe Ancients is a History Hit podcast.Sign up to History Hit for hundreds of hours of original documentaries, with a new release every week. Sign up at https://www.historyhit.com/subscribe. Hosted on Acast. See acast.com/privacy for more information.
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Hello and happy new year. Welcome to 2026 on the ancients. It's going to be a good one. We've got some awesome episodes already lined up. Our January schedule is done. We've recorded it all and cannot wait to share those episodes with you. But we are kicking off 2026 and the new year with one of my favourite ever episodes over the five years, five and a half years that we've been doing the podcast. And actually, this is an episode that so many of you have found.
deep in the ancient archive
and you've been requesting
time and time again
that we get this guest back on
at every opportunity
you want more of this guest
he's none other than Dr. Henry G
the brilliant Dr. Henry G
who we have now had on
since doing this first interview with him
all those years ago
we've had him on several times since
because he is a fan favourite
he's funny
and he makes these stories
that we cover with him
going millions of years back
kintapri history he makes them really interesting and easy to follow big complex topics as well and we did quite a big topic for our first ever interview with henry g we covered hundreds of millions of years of history of life on earth the origins of life on earth going from the earliest single cells at the bottom of the deepest darkest oceans to the rise of animals with backbones the first
fish, fossil fish with backbones to plants and trees and animals taking to the land,
ultimately to the rise of the dinosaurs. Henry covers all of this in this really fun and
fascinating interview. I really do hope you enjoy. If you've never listened to an interview
of Henry G before, well, you are in for a real treat. So really excited to get this one out of
the archive to share with you to kick off 2026. Here is Henry G, Dr. Henry G. talking through
the origins of life on earth. Let's go.
To start it all off, Henry, let's go right from the beginning, not the Big Bang, but tell us how
life on earth, how does it begin and when?
Well, are you sitting comfortably?
Yes.
Then I'll begin.
Life on Earth actually began not long after the Earth formed.
In fact, it's really quite indecently close to when life on Earth formed.
The earliest is very, very controversial because the signs are very, very diffuse and difficult to interpret.
The earliest life on Earth that everyone agrees about is 3.4 billion years old, give or take.
that's 3.4,000 million.
And that's a reef, a fossilise of a reef in Western Australia.
So that's three and a half billion years old.
But, of course, by then, life had already been well established
because this was a whole reef.
It wasn't just a little blob of matter, a living matter.
It wasn't a coral reef.
Coral was still 3 billion years in the future, which is quite staggering.
It was made of microbes,
of microbes, microbes would make a lawn on the ocean floor. And by microbes, I mean, the kind of
scum that you find on ponds, like ponds scum, blue-green, oily, what we used to call blue-green
algae, and we now call cyanobacteria, and they would form lawns on the ocean floor, and then a storm
would cover them with sand, and then the cyanobacteria would form another layer, then there'd be
more sand. So you'd have this layer of slime and sand, and slime and sand, and they'd build these
great cushion-like mounds called stromatolites and you'd get whole reefs of these
stromatolites are still found occasionally in very salty seawater where no other creatures can
live there's still a few in western australia but for three billion years they were the masters
of life on earth they were the rulers of life on earth but there are signs that stromatolites lived
as long as 3.7 billion,
basically by these little layer cake structures in rocks.
And these are found in Greenland,
which back then was in the tropics because of continental drift.
But they're disputed.
Some people think they weren't stromatolites.
They were just folds in the rock.
But life must have been around at that time,
and there are other traces.
But the earliest trace of life on Earth,
which is very disputed,
is from a tiny grain,
one grain of a mineral called zirken.
Now zirken is a mineral.
It's like cubic zirconia
that you make flashy wedding rings out of.
And this zirken was once upon a time
a grain in a rock
that has now completely worn away.
So it's called detrital zirken.
It was basically what was left after the rock
was eroded away.
and inside this azurken is a little smudge of graphite
in other words pencil lead inside this little hole
and the chemistry of this smudge of graphite suggested
that it once passed through a living organism
because of slight deviations in the variety
and in the flavour of carbon within it
and that's 4.1 billion years
old. Now, the Earth formed 4.6 billion years old, when the rest of the solar system formed.
And for quite a long time, it was a ball of magma that spent its time solidifying into layers.
So a planet isn't just a jumble of rocks. It solidifies into layers. So there's this hot radioactive
liquid metal at the core that spins and forms the magnetic fields. And then all the light froth on the
outside, which is the crust and the mantle. But for hundreds of millions of years, the planets
weren't orderly. There were lots more planets in the solar system than there are now, and they
kept walloping into each other. So at some point quite early, the infant Earth was a bit like
infants in the playground whizzing around. It was smashed into by another planet about the size of
Mars, which stripped away the whole of the crust. And this planet disintegrated, and for a while
our Earth had rings like Saturn, very early in its history, until this detritus, this remains of this
collision, agglomerated together and formed the moon. Now, the Earth and the Moon system are really
rather strange. The Earth is the only planet of its kind that has a satellite that is
similar in composition to its own parent, and that's why the impact is still a hypothesis,
but there's really no other way to explain it. And then after that,
things cooled down a bit and the atmosphere, the crust cooled and became more solid and things
kept walloping into the earth but not quite as big because by that time the solar system
had got tidied up and most of the things that hit other things had already hit the other things
and so it's more peaceful and the earth could cool down a bit without having its crust stripped
away every five minutes. In the atmosphere was unbreathable.
methane, hydrogen, and a lot of other unpleasant things, but there was a lot of water vapor.
Water is very, very common in the universe, but the outer solar system, a lot of the bodies are
covered in ice. But closer to the sun, where we are, it can support liquid water, and when
the earth cooled, all the water vapor in the atmosphere fell like rain. It just condensed into
rain, and it rained, and it rained for millions and millions of years. In fact, it would have
made Oldham look quite sunny
and it was
and there was the old comet
occasionally walloped into the earth
providing more ice and water and things
and then the earth was a world of water
and it was in that that life began
deep, deep down in the deep ocean
where a lot of minerals
superheated would jet out
from cracks in the crust
and provide the raw chemistry
and the very porous rock
surfaces in which life
began. Now, how
How life began is one of the big conundrums.
Nobody knows how life began.
People have come up with all sorts of ideas.
But the one I tend to favour in my book
is deep down in these hydrothermal vents,
as they're called these superheated, super-pressurized jets of water.
The mineral-rich jets of water would shoot out from gaps in the earth's crust,
and then they'd cool and become turbulent
and settle down in crusts in the rock.
The rock would basically form pretty much instantly from these minerals
as it met the really cold pressurized water.
And in the tiny, tiny holes in the rocks,
I mean microscopic pores in the rocks like pumice, basically,
which is volcanic rock, but it's full of little air bubbles,
so it's actually quite light.
The rock, although very light,
would provide a catalytic active surface, if you will.
The thing that volcanic rocks do very well
is catalyze organic chemical reactions
that wouldn't otherwise happen.
So if little organic molecules,
and there were loads of loads of them around,
and we know because comets and asteroids
are full of simple molecules,
the simple ingredients for life,
they would get together in the rocks
and form more complicated molecules.
And life began in these tiny little gaps in rocks
in the super-pressurized deep sea.
And one thing that life tends to do quite quickly
is form little membranes like soap bubbles.
They form all the time,
everywhere. And once you have a membrane, you can have differences in the chemistry between one
side of the membrane and the other. And when you have that, you have difference in electrical potential
between one side and the other, just like a battery. And then what happens is you have little holes in
the membrane, so the electrical potential can go from one side to the other and drive more chemical
reactions. And all life, all life, including you and me and everything we know, is based on this
simple idea of electricity. The electrical potential across a little cell membrane is huge
when you think that cell membranes are very tiny and the distance between one side and the
other is tiny. It's like millivolts. It's like the amount of power in electric guitar pickup
in the wire that's generated when an electric guitar string twangs. The electrical potential is
in millivolts. So it's a hell of a lot of electricity is suddenly generated and that put the
molecules to work. And that is how life began by these little electrically charged soap
bubbles. Now, nobody really knows because, as I say, the earliest evidence for life is
hundreds of millions of years later in just a little smudge in one tiny crystal of graphite
to suggest that there was once a living organism passed that way. So we've got no actual
fossils. But that seems to be the most likely in terms of logic and chemistry.
that life began in the sea, the evidence suggests from what we see of the most primitive living
organisms is that it was quite hot. The proteins and molecules we see in the very most primitive
bacteria suggests that they started in somewhere pretty warm, well above boiling point.
So you could say how could life begin if the water was above boiling point? Well, it wasn't steam
because it was under huge pressure. So the steam under huge pressure in water, it doesn't
become a gas. It's superheated. So it stays in a liquid up to like 2 or 300 degrees. So everything
we know points to an origin in a very hot, very high pressure environment and with the addition
of volcanic rock surfaces to provide the milieu in which the early chemicals of life could come
together without just diffusing into the ocean. And in these tiny little rocks, so they didn't
have anywhere to diffuse to, form nice little concentrates. That seems to make the most sense.
Now, in my book, a very short history of life on earth, I tell it like a story, but in the
footnotes, I give more or less evidential support. Now, the origin of life, I say, is one of the
areas where I'm basically making it up, but I'm trying to make it up based on what evidence we
have. So that, I hope, is an answer to your question, but it would be only an answer. And
you could get two scientists and you'd get three different opinions about the origin of life
on Earth. Yeah, Henry, it absolutely is an answer. A really, really interesting answer as well.
Well, let's move forwards then from that. I mean, I guess there is still lots of debate,
lots of theories, lots of we don't know about this next stage before we get to animals proper
and all of that.
But you mentioned cyanobacteria earlier.
So do we know how things go from these really, really small organisms at the deepest
depths of the ocean?
Do we know how they get to the shallow waters and you get the emergence of this cyanobacteria?
All we know is we can track them ecologically because the cyanobacteria form these
layer cake-like mounds, which are called stromatolites.
And these are found to this day, and they are found very commonly, they're the earliest
form of life. But by 3.7 to 3.4 billion, the life had spread from the very dark depths of the sea
to the surface waters and into the sunshine. And sunshine had two huge effects on life. One is
the ultraviolet rays would be very toxic. So what evolved was sunscreen, pigments that would
protect that absorb the ultraviolet light and stop the bacteria burning up because the one thing
that is really good for cleaning on getting rid of bacteria is ultraviolet light. This is why the
best way to clean your wet washing is to hang it up in the sunshine because the ultraviolet light
will kill any bacteria in it. I mean absolutely that's what it does. It will kill it dead
tautologically like well-known brands of bleach. So what the bacteria did was evolve pigments to
absorb that ultraviolet radiation. But one thing life does is turn a problem into an opportunity.
So once the energy was absorbed, it could be used to do things. So the energy was used to create
food. The earliest living forms, one of the things they did was to do chemistry with compounds
of iron and sulphur, of which they're lots in the deep sea, using these little batteries by pushing
things to and from the membranes, they could get energy out of iron and sulphur compounds.
But when they were up near the surface, they could use this fantastic new sort of energy
sunlight to split water into hydrogen and oxygen. And that is the most efficient and best way
to get energy out of their biosphere. And that's what plants still do today. It's called
photosynthesis. And they use a green pigment called chlorophyll, which is why plants are green
and why we're as to about the green movement
and being more green,
it's to do with plants and plant growth
because that's how plants are at the bottom of the food chain
and including the plankton that live in the sea.
You can see this for my T-shirt.
Your listeners can't see this.
I'm wearing a T-shirt which says happy plankton
and it's got lots of cheerful little plankton
and one of them says,
where the bottom of the food chain, hooray!
So the modern food chain started with photosynthesis
when plants used a pigment
and bacteria, they use different pigments,
but they still do the same thing,
to create energy out of water.
Water is one of the most abundant substances in the universe.
The whole of the planet was completely covered in it.
So when you have sunshine and a pigment that harnesses the sunshine
and used it to split water, bingo, life really took off.
Unfortunately, there's a problem with water,
and that's one of the byproducts.
the hydrogen was used to shuffle throughout the membranes,
but you get this gas called oxygen, which comes off.
Now, there wasn't any free oxygen in the atmosphere or the ocean at the time.
There probably was a bit, but really as a tiny, tiny trace.
A life had evolved in the complete absence of oxygen,
and molecular oxygen is very, very highly chemically reactive.
In fact, it's one of the most dangerous poisonous substances in the universe.
So when oxygen was released,
it caused the first mass extinction of organisms that died out.
Now, there's still bacteria around for which oxygen is extremely toxic.
One of them is botulism organism that you get Botox from.
Botulinum toxin is actually one of the most poisonous toxins known,
and it actually paralyzes muscles,
and that's why it's used in Botox,
because it actually tiny quantities, it paralyzes muscles.
so people with Botox treatment have no lines
but they can't really talk
or they can't move their faces very much
because their muscles are paralysed with this poison.
Anyway, the bacteria that Bottyline and toxin comes from
is evolved in the complete absence of oxygen
and it thrives in badly canned food
if their food isn't properly sterilized before it's canned
and there's no air in it.
These oxygen-hating organisms can thrive in such a thing.
So the earliest organisms, they weren't botulidin bacteria, but they were oxygen-hating bacteria.
So the first mass extinction drove legions of these to extinction when oxygen was released into the atmosphere.
So that was one of the first catastrophes of the earth when oxygen was released.
But the next major activity happened, also related to oxygen, roll the ancient tape of life forward from about 3.3.3.3.
5 billion to 2.5 billion, and there was an event called the Great Oxidation Event, where for reasons
not entirely clear, there was a huge pulse of oxygen released into the atmosphere, probably more
than there is in the atmosphere today, which is 21% by volume. It's about a fifth of the air we breathe
as oxygen. And then it subsided to something very, very small, like 2%, which is still tiny. This
is probably related to a lot of tectonic activity. The crust is divided into these tectonic plates.
They're forever bashing into each other, sliding underneath each other, and creating volcanic
activity. And that builds new land, because there wasn't any land to start with. If you think
about places like Iceland, you see new islands, volcanoes forming all the time, and these produce
new islands. And that was basically how all the continents formed originally. So there were
any continents, they all started as these volcanic eruptions from the bottom of the sea.
But one thing that this new rock does when it comes above the atmosphere is it absorbs carbon dioxide
like anything. It really sucks it up. It's called weathering and it forms carbonate rock.
Now, when all the carbon dioxide is sucked up into the atmosphere and there's nothing for the
oxygen to react with, the oxygen reacts with the rock, the carbonate.
dioxide. But when all the carbon dioxide is sucked out of the atmosphere, that, of course,
wipes out the greenhouse effect. Now, we're all very concerned about the greenhouse effect now,
but in the earliest days of the Earth, the sun was actually much dimmer than it is now.
It's been slowly increasing in brightness throughout the history of the Earth. But then it was
much dimmer, and the only reason that the Earth had a liquid ocean was because it had
lots of carbon dioxide in the atmosphere to fuel the greenhouse effect to keep the earth much warmer
than it otherwise would have been. So when this pulse of continental mountain building happened
about two and a half billion years ago, that sucked up all the carbon dioxide, chilled the earth
and it went into the deep freeze. The earth was completely covered in ice, and I mean completely,
all the way from the poles to the equator, for 300 million years. Of course,
one great thing about ice is that it tends to float. So there were still things happening in
the bottom of the ocean. But life, if it had a motto, would be whatever doesn't kill you makes
you stronger. So that event fueled the next change in the history of life, which was the
bacterial cells got together into a new order of existence, which is they formed proper cells,
nucleated cells.
Talk us through this next stage in evolution.
Is this this nucleation of cells, does this ultimately ending up with, let's say, multicellular organisms?
You're way ahead of me, Tristan. You're rushing ahead.
Okay, you slow me down.
So what happens with bacteria is bacteria.
are famously sociable and gregarious.
Now, we saw this with the stromatolites.
They formed layers of bacteria all living together.
But it wasn't just this one kind of bacterium cyanobacteria.
There were all sorts of other bacteria.
Because the thing about bacteria, there are two things.
One is they can live on virtually anything,
and different bacteria specialize on eating different things.
Some live on methane, some live on iron and sulfur,
some live on other things.
And one bacteria's waste product could be another bacteria's food.
So they tended to live together in these communities where they would trade chemicals.
So some would prefer other things.
And the other thing about bacteria that they do is they're really rather free and easy with their own genetic material.
They would trade genes like little kids swapping trading cards in the playground.
If kids still do that, they did when I was a kid.
And that's what happens now.
If a bacterium comes across a new antibiotic, the way it will combat it is to pick up a little bit of DNA that happens to have a protein that breaks down the antibiotic.
So that's how antibiotic resistance happens really quickly because bacteria pick up antibiotic resistance genes from other bacteria.
So you've got to think that bacteria is a community of different species swapping food, swapping waste, swapping information, swapping chatter.
so bacteria always live in these communities
and some of them are very difficult to get rid of
that's one of the reasons that these things called biofilms
they're called are so successful
for example in people who have cystic fibrosis
what happens in the lungs is their lungs get too full of mucus
and this mucus is a wonderful place for all kinds of bacteria to live in
so they form biofilms which are very very very hard to get rid of
and that's what happens inside
So biofilms still happen.
These were the things that were coaching the surface of the sea
because there was nothing to eat them billions of years ago.
There were no animals.
But what happened in the Great Oxidation event
when the Earth went through this crisis
was bacteria took this communal living to another level
rather than having lots of little bacteria swapping stuff,
but each one doing everything itself.
They took a leaf out of Adam Smith and the wealth of nations
they formed communities where each bacterium would do the thing it was best at
and leave the other jobs to different bacteria.
So bacteria started living in a common membrane where some, the cyanobacteria,
would do what they were best at, which was catching sunlight
and getting the energy out of sunlight.
And then there were other bacteria called the proto-bacteria
that were great at digesting food.
And these were the distant ancestors of the things.
called mitochondria we have in ourselves. There's a little tiny pink power packs that produce
the energy. And then there were bacteria that were good at accumulating all the genes and
becoming the library and repository of all the DNA. And they pulled in all the genes from
cyanobacteria and the proteobacteria. So mitochondria and chloroplasts, the green bodies in plants
that harvest sunlight, they still have DNA from their ancient origins, but not very much.
because they've subcontracted all the DNA business to the nucleus, and it lived in a common membrane.
And the thing you can do, if you've done the Adam Smith wealth of nations, is each cell can do much more than the sum of its parts.
It becomes much more efficient. It can do more things, more economically. It can go bigger. It can go further.
it can digest more, it can acquire more resources.
So in a world of death, in a world which is having difficulty,
that's when nucleated cells evolved in that period
about two and a half billion years ago.
Now, the great glaciation faded, as they all will,
but it took hundreds of millions of years.
And these nucleated organisms called eukaryotes,
which is basically Greek for nucleated organism,
you're a Greek fan
you probably worked all this out
so
another happy billion years
went along where the eukaryotes
started to diversify
now most of them
remain single-celled like
amoebas and things like that
but some of them became
multicellular because that's
another stage in organisation
some of them glommed together
to become multicellular
organisms and about
900 million years ago, so we're going for billions to hundreds of millions now, so we're getting
really close to modern days now, where a billion years ago, they started to form what are
recognisable as algae, you know, seaweeds and early fungi and the very, very earliest animals,
sponges appear about 900 million years ago. And so the period between about 1.8 billion and
800 million years ago
is known as the boring
billion to geologists
who really only get out of bed
if they've got some world-shattering
apocalypse to wake up to.
So the Earth was quite happy for a billion years
slowly brewing and evolving
these little creatures, some of which became
multicellular. But
then there was another episode
of continental
fuss and brew
ha-ha. Well,
yeah, what happened is all
these volcanoes, you remember all them making continents. The continents started to get bigger and
bigger, and of course they keep moving around. Now, lots of small continents would glom together
to become supercontinants, and then these would split apart, and then they'd come together to form
a supercontinent. So there is a kind of supercontinent cycle with a period of about half a billion
years. And this has explained really well in a book by a friend of mine called Ted Neal,
who's a geologist, and he's called his book Supercontinent, which he wants to assure people
is not about pelvic floor exercises. It's, and it explains the supercontinent cycle.
So at about 850 million years ago, there was a supercontinent where most of the land masses
were concentrated called Roginia. And that started.
to break up and rift. And that formed a string of continents, mostly around the equator.
Now, the thing about the tropics is that's where weathering is really intense. I mean, if you've
been to the tropics, you've seen tropical storms, you'll see how roads are just washed away
by rain and heat and humidity. Well, that was always the case. Now, what that weathering did was
it did the same old thing. It sucked carbon dioxide out in the atmosphere, and there were more ice ages.
And these lasted for only 80 million years.
They did cover the whole of the earth, but only for 80 million years.
Even though there was more land to weather, the sun was that much hotter by then.
So that fueled the next step change, which was the evolution of animals.
But the problem with animals, animals really perfected consuming oxygen, this poison.
Animals need oxygen and they need lots of oxygen.
but they couldn't evolve until there was enough oxygen to live on.
And although there was gradually more oxygen in the atmosphere and in the ocean,
it wasn't very much.
It was only enough for animals with very slow metabolisms to live on.
And these animals are the sponges.
Sponges are very, very simple animals.
They don't have any organs or tissues.
They're just bundles of cells.
with lots of channels between them,
and the sponge shells waft any old detritus,
bacteria, waste products, rusty bikes, old brass bedsteads,
leather boots, half-eaten pork pies into them, and metabolise them.
And what that does is it frees the ocean
of anything that decay bacteria can live on.
So over tens of millions of years,
the sponges made the ocean much nicer and,
less stagnant and have more oxygen in it.
And that allowed bigger animals to live in the ocean.
There was another thing that was fueled by the increasing oxygen,
and that was the invention of the anus,
which was one of the great underappreciated episodes in evolution.
It's what happens in very simple animals like jellyfish.
They're basically cup-shaped.
They have a hole at the top or the bottom or the side
or wherever, there's really no distinction.
And that's where all the food goes in,
but it's also where all the waste comes out.
And it's a kind of diffuse wash of ammonia,
and that's chewed up by decay bacteria all around,
and that sucks out all the oxygen.
But some organisms invented or evolved a through gut.
So all the food came in the mouth,
but didn't go out of the mouth.
It went all the way through and came out of the anus at the other end.
And that allowed animals to grow bigger,
and it produced pellets, fecal pellets,
and these, rather than washing in the atmosphere,
drifted to the bottom of the sea.
And, of course, the bacteria followed it.
Wush, it was a race to the bottom.
And all of a sudden, well, sudden, in geological terms,
the ocean became much more clear.
The ocean cleared and was oxygenated,
and that's when animals happened.
And the thing about animals with a mouth at one end
and an anus at the other end
is for the first time
they have a direction of travel
and an animal with a mouth at one end
and the anus at the other end
can move around
and it's usually looking for something
and there's something it's looking for
is something to eat
and so they started eating
all the slime
that covered the ocean floor
and they started burrowing
underneath the slime
and then when they'd made burrows
and they'd eaten all the slime
which had a terrific effect
on the ecology of the earlier
they started eating
each other. And that's when the fun started. Henry, we're going to keep going from there,
but you've kind of answered it already, but I had to ask this question because it's amazing.
It seems like these sponges, they changed the world. They did. During the writing of this book,
when you write a book, you change because of the things you find. And I have a great appreciation
for sponges. But things change all the time and knowledge changes. When I was writing the book,
there was only very tentative and controversial efforts
that sponges existed as long as 900 million years ago,
which they'd need to to work on this scenario.
But as the book was finished and not yet published,
I was happy to have on my desk at Nature
a report of the first fossilised sponges
about 900 million years old.
These are still very controversial.
Not everyone will believe them.
The thing about sponges is some sponges
leave little mineralized spicules.
They're beautiful tiny microscopic grains
that they make out of calcite or silica.
And these can be preserved in the rock.
So the actual organic matrix of the sponge isn't there,
but you see these little speckules.
But many sponges don't have these.
They have more of a protein matrix
that they're based on.
And these are the same sponges
that the Romans made bath sponges out of.
These are bath sponges.
So the earliest sponges seem to have been the distant ancestors of bath sponges.
And they only leave their signs of their passing as textures in the rock, the ripples in the rock of where they were.
And that's why they're very distinctive, but it's still very, very controversial evidence.
So that just got published while the book was in press.
So yay for sponges, that's what I say.
Yay for sponges indeed, Henry.
it is absolutely astonishing.
And you mentioned how the fun really begins
when animals starts eating each other.
So talk us through the next stages, as it will.
What goes next in this great evolution story?
Well, after this whole episode of glaciation
that lasted a mere 80 million years,
that's when you start to see animals.
It seems to be that animals were the next stage in organisation.
You have creatures that were not only you carry,
not only multicellular, not only sponges, but animals that could move around. They had muscles
and they could actually move from one place to the other, and they had a mouth at one end and an
anus at the other, so they could eat things. Now, this didn't mean that they all did this,
but the next phase of evolution was a really, really strange phase of early animal evolution.
when the animals were soft-bodied
and quite gentle things
some of them looked a bit like jellyfish
some of them looked a bit like modern sea slugs
they were large enough to be visible
I mean they were the size of a saucer
and segmented
but pancake flat and could move along
like flat worms do on the ocean floor today
and there were some animals that
seemed to stay where they were
They were perhaps colonial animals like some sponges are like many animals are,
moss animals and all kinds of jellyfish and so on.
And they look like platted loaves.
And they reproduced by sending out suckers like strawberry plants
to make baby platted loaves all around them.
There's evidence for this in some rocks now in Newfoundland.
And these animals lived in what was called the Ediacaran period,
called after Ediacura, a mountain range in South Australia.
where these fossils of these animals were first found.
Now, the Ediacaran period was 60, 70 million years long,
and the later Ediacaran animals look a bit more mobile than the earlier ones.
You see things more like mollusks, like snails and slugs and worms
that were more mobile than the more plaited loaf kind.
They look like fronds.
They're found today in all kinds of remote romantic locations,
such as South Australia, Northern Greenland and Leicestershire.
So these rocks just crop up everywhere.
But then was another cataclysm.
For reasons that are not really known,
all the earth's surface,
all the crust was scrubbed into the ocean
right down to bedrock
by an intense burst of weathering.
This was a puzzle for a long time.
It came at the base of what's known as the Cambrian period,
and this was a puzzle for Darwin
because before the Cambrian period
there didn't seem to be any fossils
but from the beginning of the Cambrian
there were loads and loads and loads of fossils
as if animals had suddenly appeared
as if from nowhere.
Now this was before the Ediacron fossils were found
which were all of soft-bodied creatures
and you've got to bear in mind that most fossils
are formed from the hard parts of animals
the shells, the teeth, the bones
anything that's been mineralised
Now the Ediacran animals were unmineralized
and they're only preserved
as very faint impressions on sandstone
but all of a sudden at the beginning of the Cambrian period
there were mineralised animals
it was known as the Cambrian explosion
because it did seem to happen all at once
and for a long time geologists wondered
because they seemed to be what was known as erosional surfaces
there were surfaces from which it looked like
things had been scrubbed
and then there were these animals
so geologists thought maybe there was this lost
period in Earth's history where all the rock that had been developed but was then scrubbed away
that was the period in which all the evolution happened so the Cambrian explosion was actually
slower we just missed the bits where it was happening but now there are very refined techniques
of dating the rocks using radioactive decay of minerals it really was explosive and it happened like
this when this massive erosional episode happened that scrubbed all the I won't say soil because
there wasn't any soil, that happened later, all the surface rocks into the sea, that did two
things. One is it raised the sea level a lot, and that made a lot more places for animals to
live in, because most creatures, even today, live in shallow seawater round continental margins,
the continental shelf. That's where most things live. And the other thing was, all this
rock that was scrubbed into the, it was full of minerals. It was full of calcium minerals.
calcium carbonate because of all that carbonate rock that had been formed when carbon dioxide
was weathering the rock and calcium phosphate was another one and this was a bonanza for
animals that had started to eat each other because they didn't have any teeth they would sort of
suck each other to death and all the animals that were sucked to death couldn't do anything about it
because they didn't have any armor so all the minerals allowed for two things it was an arms race
animals that used to suck each other to death
evolved teeth
so they could chew each other to death
and the animals that were being chewed evolved armour
and it was usually shells
made of calcium carbonate
and in the vertebrates bones
and teeth made out of calcium phosphate
which is what our teeth and bones are made out of
so all of a sudden at the beginning of the Cambrian
there's an evolution of animals with hard parts
that would fossilise well
coincidentally and it was all to do with animals
starting to eat each other.
And in the Cambod
you have the appearance
in the fossil record
of lots and lots of strange things
we don't see today
like trilobites.
Now everyone knows trilobites.
Every geologist,
every rock hand will have a trilobite
and they're kind of like
giant woodlice
and they lived in the sea
and they were very common.
They're very beautiful,
very sophisticated creatures
but there were lots and lots
of other kinds of creatures
that are less well known.
Also, mollusks with hard shells,
clams and snails started to appear
things like starfish and sea urchins, the echinoderms, the spiny skin creatures,
and even at the end of the period, the first fish, and there were very soft-bodied fish
to begin with, but at the end of the Cambrian, heavily armoured fish evolved, and these
armoured fish were armoured because they had a mortal enemy for millions of years, which was
a major driver of revolution, and these were these horrific giant sea scorpions called Euryptorids,
and some of them were about 10 feet long
with huge pincers and great big goggly eyes
and so as long ago as 1933
a famous paleontologist called Roma
speculated that fish evolved armour
as a defence against being eaten by these gigantic sea scorpions
it's a good idea
and it's highly likely
I mean we don't have any proof
but all these things happened at the same time
in the Cambrian period about 540 million years ago
was this Cambrian explosion
which was a sudden arms race
driven by the sudden appearance
of a lot of calcium minerals in the sea
and all the animal groups.
Actually, nature loves these exceptions.
For a long time,
all the animal groups that we now know today
originated in McCandrine
except one,
the bryozoa, these moss animals,
which most people haven't heard of,
but they form little colonies.
Some things which look like seaweed
called dead man's fingers,
are actually tiny colonies of these colonial animals.
But another scientific report that appeared while this book was finished
showed they were Cambrian bryozoa.
So even that whole embarrassing gap in evolution has now been plugged.
So all the major animal groups and quite a lot of groups that we don't have today
originated in the Cambrian.
And that was basically the start of modern times.
That was what you would call late antiquity.
It's 540 million years ago the Cambrian explosion.
Well, beat that fall of the Western Roman Empire right there.
Henry, the Cambrian explosion, huge, this huge events in prehistory.
I've got to ask them the next big question.
You probably know where I'm going to go over this.
If we've got all these animals now in the water that's teeming with life,
when do we start to see animals moving on to land?
Well, Tristan, I'm glad you asked me that,
because again, it was quite a long story with a lot of precursors.
Creatures like fungi and algae tend to get together to form things like lichens, and these are very resistant.
And there is some evidence that lichens and fungi and other plant-like creatures were starting to inhabit fresh water, like lakes and ponds.
About 1.2 billion years ago, there's evidence from rocks in Scotland of that age, which were deposited in fresh water.
and they show communities of little cells of algae and fungi
and they would have started forming crusts
along the water line that would have become resistant desiccation
which is the important thing
but the thing about moving on to land
land was as hostile an environment to life as empty space
because for a creature in the water
it doesn't have to worry about bearing its weight on land
because it's supported by the water.
It doesn't have to worry about breathing
because it absorbs all the oxygen from the water
through its surface or through gills, the wet membrane.
It doesn't have to worry about getting rid of wastes
which you just diffuse into the water
or just shoot out of pellets.
It doesn't have to worry about drying out.
But on land, anything that gets above the water line
is going to be crushed, desiccated and asphyxiated
in pretty short order.
So some creatures started to do it, some bacterial slime by having a coating of mucus,
which would, like a spacesuit, protected against desiccation.
And if they were thin enough and wet enough, they could absorb oxygen from the dry air.
And so very slowly, slime and various encrusting lower organisms would start to colonise the shoreline.
And then in the Lake Cambrian
and a bit later than that
some actual plants
started to come ashore
but very simple things like
mosses and plants called liverworts
which are a bit like mosses
that you can still find today in very dark, damp
places like around
shady waterfalls and
places like that and rocks that are covered
in water a lot of the time
these would start to colonise
the intertidal zone. Now the intertidal
zone where the land is
covered by the sea twice a day and was completely dried out for twice a day.
It's a very tough environment for animals and plants to colonise,
but they started to do that.
And very, very slowly, there became a covering of plants over the land near water
and slightly further away from water.
The earliest plants evolved tough, woody tissues that allowed them to grow upwards,
because once the plants had colonised the land
what they wanted was access to sunlight
and they would compete each other for access to sunlight
so they'd start to outgrow each other in height
by outgrowing each other in height
we're talking about centimetres at this time
but once you start having little plants growing on the land
you can start having little animals
these have been now supported by mineralised skeletons
like little crabs and lice and early types of insect
and spiders and harvestmen.
These started crawling on the land,
fighting tiny to the death battles
underneath the covering of plants
which would screen them from the sun
and conserve moisture.
Then slowly, slowly, slowly,
soil starts to form.
Soil is another great, underappreciated
feature of evolution.
And one of the worries about deforestation
is not so much getting rid of trees
is because trees have roots that keep the soil in place.
And once you get rid of the plant,
soil is completely washed away
and soil is necessary for holding water
for conserving life. It's full of life.
So once plants had roots and fungi attached to the roots
that broke up the soil and there were dead plants
and dead animals in the soil
and bacteria are in the soil and fungi in the soil
basically making compost out of rock
and organic matter, you started to have soil
and that started to be colonised by tiny animals and plants
and was a growing medium for plants.
So it took a while for this to happen.
But, of course, what you're dying to know is when the first fish came on land.
That took a while because fish were bigger and had more to support.
Well, from the Cambrian onwards, fish, which were vertebrates that had backbones, they devolved,
through to the Devonian period, which was about 400 to 350 million years ago,
or they're about, someone's going to kill me for getting the time's wrong,
but I'm just working for memory here.
That was what we always used to call the age of fishes.
The oceans were full of fishes of all kinds.
Some were enormous.
And, of course, it was all full of other predators
like these gigantic sea scorpions, which I mentioned.
But the great thing about land,
life, as we've seen, turns problems in light.
They've all been on management training courses.
There are no problems and difficulties.
They're just challenges and opportunities.
And land was a whole challenge and opportunity.
It was difficult to colonise, but oh boy, if you could do it, you'd have it to yourself
without all these other fishes bumping each other and getting all crowded in the sea.
Now there was a group of fishes called lobefin fishes because their fins were supported on little legs.
Well, they were just like little legs, only they terminated in fins and not fingers.
Some of these were quite big, and they tended to live in very shallow freshwater and in the shallow seas.
and they lived very close to the surface of the water
and they were ambushed predators
they used to hang around until something would turn up
and then they just go snap and swallow it
so they were quite big
some were kind of alligator-like
in that they were flattened from top to bottom
rather than side to side like fishes tend to be
so they could cruise along the rivers
with just their eyes showing
waiting for some unfortunate insect
to fall into the water or another fish to come along
and these were the creatures that started to colonise
the land because if you're living in very shallow water, sometimes the water can be so shallow
it disappeared altogether. So while still in the water, some of them traded fins for digits.
And at first they weren't really worried about how many digits they had. Some of them had eight
digits per limb, some had seven, some had six. And these appeared towards the end of the Devonian.
These kind of basically they were fished with legs. They had legs, but they couldn't have lived for any
length of time out of water because they still had internal gills.
But some of them had lungs. In fact, all fish evolved with lungs. It's just most of them
have lost them and turn them into other things like high thigh cabinets and swim bladders
and other things. So they breathe through their gills. But some of these lobefin fishes
started to trade their gills for lungs and actually only breathed air. Now, there's still
fish that do this. They're distant relatives of what we call tetrapods, that is four-legged animals.
When lungfishes were first found, they were mistaken for salamanders.
Now, the Australian lungfish has got scales and lives in rivers and looks very, very prehistoric.
But the South American lungfish can only live in air.
It's a fish, but it cannot live full-time underwater.
It has to breathe air, because it doesn't really have any gills worthy of the name.
So animals like this started living in the water margins, and they started colonising the land,
and the land was full of wonderful insects to eat, because,
they'd all been colonized in the land.
So you started to get what were the first amphibians,
these animals that live first in the water, first in the land.
Now, they were rather different from the amphibians we see today, frogs and nukes.
These evolved much later, but they were distant cousins of them.
So they lived a kind of halfway existence.
They could live on the land,
but they were tied to the water for reproduction for a long time
because they still had spawn or very soft-shelled eggs that had to be laid in water.
So that was the amphibians.
They started to colonise the land around 360-ish million years ago.
And there were quite a lot of different ones.
There were some that were more evolved for living in water.
And there were some that were evolved for living in land,
although back then they would have just seen it as a different kind of water.
It was just water of negative depth.
So there were kind of fish that lived out of water, really.
And that's with the early amphibian.
But, Henry, soon enough, it seems to be a similar trend that we've been having with earlier times.
There is a great natural event which almost stymies this.
Well, there were all the time, but the first one was rather an abundance of life rather than a catastrophe, and that was the evolution of forests, because once we started having little plants growing to enormous heights, I mean, oh, centimetres above the ground, they evolved hard woody tissues which could support much higher trees. And the first forests evolved in the Devonian. Now, the forest trees didn't look much like trees now. The first forest trees
trees were basically giant thungy. I mean, they were really weird. They were the sort of thing
that the caterpillar and Alice in Wonderland would have sat on top of smoking his hash pipe.
But then the trees were relatives of little, what we now call weedy water plants like
horse tails. You know the field horse tail? Beautiful plant. Absolutely persistent weed only
grows so high. But back in the late of only in the Carboniferous period, they grew to 50 metres
high. And there were other things which were club mosses, which now grow to a few inches high.
They grew to 70 metres high. And this was during the Carboniferous, now the clues in the name.
This was the period in Earth's history where most of the Earth's coals formed. And it happened
because of the way that some of these club mosses called Lycopods grew, they didn't have
heartwood. They were supported by a rind of tissue on the outside, a bit like some giant reed,
but they grew incredibly fast and very, very wastefully, because most trees now, they grow up
and they stay up and they support their reproductive tissues and their leaves high above the
ground. And the reproductive tissues, you know, the flowers and the fruits, they come each year,
but you still have the whole structure. But that wasn't true with the first foot,
forest, they started in the ground and shot up like some very slow-moving firework until there
were meters above the ground and then they produced the fruiting bodies which are like cones
and spread spores everywhere and then the whole tree would just die. It wouldn't stay up to do it
next year. It would just die and it would just stay there rotting like a trunk without any
branches and eventually collapse into the ground. And this would use an incredible amount of carbon
carbon dioxide so what happened with two things in the age of the coal forest is an immense amount of
decayed and half-decade plant matter was accumulated on the land and it wouldn't have looked like a forest
I was trying to imagine what it would look like and in the book it was more like a World War I
battleground because it had all these like if you see pictures of the First World War you know
after the forest and woodlands have been battered they just looked like a bleak landscape with the
occasional tree trunk sticking up and because these
plants didn't have solid trunks. They had hollow trunks. You had these craters sitting on the
ground, like bomb craters all over the place, with trees everywhere. And the craters were great
for little amphibians to lay their eggs in and insects to live in. But it wouldn't
have looked much like a forest now. And in that period, huge deposits of this vegetable matter
were deposited from the carboniferous and into the subsequent Permian period. And in fact,
90% is staggering.
90% of all the world's coal reserves
were formed in this one period
of about 70 million years
when the lycopods were evolving.
But then they caused another catastrophe.
Well, that and continental drift,
we'll come to that.
They use so much oxygen
and so much carbon
that they precipitated another ice age.
They pulled all the carbon.
You know, we have to plant a tree
to suck carbon dioxide out of the atmosphere.
well you can have too much of a good thing
in the carboniferous times they sucked
so much carbon out of the atmosphere
they created another ice age
but they only did it at the South Pole
because the continents
had come together after the fragmentation to form
large continental land masses
and the one nearest the South Gondwana
was over the South Pole
and they were glaciers over the South Pole
that was the Carboniferous Ice Age
it wasn't the whole planet
there were actually other ice ages which
I haven't really talked about, which were
catastrophic and led to extinction
and origination, but I've kind of
glossed over those. But the carboniferous
one was quite important because
it coincided with
the slow formation of another
supercontinent. This is the one everyone's
heard of, Pangaea, where
almost all of the
continents coalesced to form some
gigantic landmass from the south
pole, it covered the south pole, almost
to the north pole. And if you
looked at it, it would have formed a sea shape
There was a great gulf called the Tethys Ocean, which was about over the equator, and that had incredible coral reefs, but also absolutely terrific monsoon rains, which were just spectacular.
And one of the problems you get, when you get a lot of little continents forming into one big continent, is you get less margins of the continent because the margins get glom together and form mountain rages.
So that meant less room for animals to live in.
So life was getting tough.
And also because after the carboniferous, plants became less profuse.
So less oxygen was being diffused into the atmosphere.
So pangir was quite tough.
There was less life in the sea.
And also breathing on land became quite tough.
It was like breathing in at the high mountains.
In the carboniferous, the plants had produced so much oxygen.
that even though the forests were damp,
they could be set alight by lightning strikes,
even though they were damp,
because it was so much oxygen,
even wet sticks would burn.
And because it was so much oxygen,
that could fuel the growth of giant insects.
So there were dragonflies, the size of crows,
and there were millipedes the size of magic carpets.
And there are, again, these giant sea scorpions
that kept coming to get their age-old prey,
the tetrapods, which thought they could cunningly escape
by evolving little legs and crawling onto land,
but oh no, that's none of it.
Some of the biggest of the sea scorpions lived on land
doing the coal measures times.
But when Pangaea formed, all that was swept away.
The life became much more difficult.
What you tend to find in big continental land masses
is very far from the sea.
They become deserts because there's no rainwater.
And so the interior of Pangaea was a desert, very, very hot.
and in the more temperate regions
plant life was less diverse than it was
and then this was leading up to the greatest catastrophe
of the last 500 million years
this was the siege of Constantinople
and the burning of the library of Alexandria
and Thermopy and all the catastrophes
you can see in the ancient world
all rolled into one squared
Pompeii as well isn't it?
Yeah very much so it is very similar
sometimes the volcanoes are not just caused by continents bashing into each other
sometimes a plume of lava comes from very, very deep in the earth
and rises upwards and punctures a hole in the crust
and this is kind of what's happening in Hawaii now.
Hawaii is in the middle of a continental plate, the Pacific plate,
but what happened is there's a plume of magma that started to arise several million years ago
and punctures a hole in the crust forming volcanoes
What happens is that the plume of magma stays still, but the continental plate moves above it,
puncturing it every so often, a bit like a sewing needle, puncturing material as it moves.
So you get a chain of islands, you get what's called a volcanic island arc.
So all the oldest Hawaiian islands have been eroded away to tiny atolls, like Midway Atoll.
And some of the islands that are kind of old like Cowai are very jungly and eroded
and not much in the way of volcanoes.
And then you get to the big island where they're still active volcanoes, which are creating new land.
And just about to surface, there's the Loe He Seamount, which is a volcano in the act of coming to the surface.
So this is what's called a magma plume, and these have happened many times, and some of them are really, really big.
Well, towards the end of the Permian period, one of them punctured the surface in South China, which was kind of a shame because South China was the land that time forgot.
when Pangaea started to get dry, South China still had these carboniferous-style coal forests,
you know, as if it was living in some prehistoric past.
But the magma plume wiped all that out, and it filled the atmosphere with carbon dioxide, acid rain, and noxious gases and the lot.
Now, that wiped out a lot of life on Earth, but that was only the hors d'oeuvre.
That life was just beginning to recover from this when an even bigger magma plume,
punctured the earth in what's now western Siberia, which was in the north of
Anglia. Now, that spewed an amount of basalt almost as big as the continental United States
over a period of half a million years to several miles deep. Now, that would have produced
an immense amount of carbon dioxide was spewed into the atmosphere, which caused the
temperature to rise by about six degrees. But also, the carbon dioxide in the atmosphere would form
carbonic acid in the atmosphere, and that would be rained out as acid rain. And also it
produced hydrochloric acid, and that would form these little chlorine compounds, which would
destroy the ozone layer. This is why we don't have chloro-fluorocarbons anymore, because they
punch a hole in the ozone layer. But these can be produced naturally. And so, every,
kind of disaster that could happen, happened. And 95% of all creatures in the sea and over 70%
of all creatures on land were killed in this maybe half-million year period of the end Permian
mass extinction. They were either dissolved by the acid or they were grilled by the sun or boiled
or fried or asphyxiated or covered in lava. So that was an immense disaster. Of the major mass
Extinctions that have punctuated the Earth history that we know of in the past half billion years,
that was by far the biggest.
And it took the Earth several million, maybe 10 million years to recover from that.
But recover it did, because it always does.
Henry, that is absolutely mind-blowing.
You have the extinction of all these herbivores, carnivores, omnivores, all of these species.
But it does beg the question, as you said there, how does life recover?
cover from this horrifying extinction event?
Well, before this extinction event, in the Carboniferous and Permian, a new kind of
animal had evolved, and these were the reptiles.
And by reptiles, I mean that loosely, these reptiles include the ancestors of mammals and
birds, and they had come up with a new way of protecting their spawn.
Now, frogs and toes and other amphibians lay their eggs in the water, because they have
to return to water to breed.
There's still that last vestige of the sea in them.
But the problem of having all this spawn around is it's a wonderful free snack for anything that comes along.
So frogs now and amphibians in the past probably came up with all sorts of cheeky ways of avoiding this.
They would either keep the spawn in their own bodies or the spawn would happen really quickly
or they'd lay it in little holes in tree branches where nobody could get to them.
Amphibians do that now.
So there's no reason why they didn't do this in the past.
But another cheeky way that amphibians evolved was evolving spawn with hard-shelled eggs.
So there was a layer of shell, which was probably more like kind of paper when it started.
It was more kind of dry and papery.
But another consequence of that is, as well as just evolving protection,
it evolved basically a whole life support system that could resist desiccation.
It was like a life support capsule.
because in it the embryo had lots of yolk to nurture it while it was growing
and it also had another membrane that would take on all the animal's wastes
so it wouldn't poison itself
and it had a breathable membrane that would allow air in and out but not water to escape
that's called the amnion and after that it would have the shell
which would be mineralised to something thing now we still have that
in fact human babies are still like that we have all of those
membranes except for the shell. We still have the amnion in which the embryo is. When a pregnant woman
says her waters have broken, that means the amnion has ruptured and she's ready to give birth. So even
though we don't actually lay eggs anymore, we still have all those membranes that the earliest
amphibians turning into reptiles evolved. And before the mass extinction, some of the
amphibians, most of them stayed around water and became quite large and predatory, but some of them
made a stab of a much more land life, because once you've evolved these eggs, you don't have
to lay them in water anymore. You can incubate them in a warm midden or in a nest or something
like that. So some amphibians turning into reptiles became quite large herbivores and carnivores.
But that was only a brief dalliance with landlife for amphibians. The N-Permin extinction got rid of
all these very pretentious land-living amphibians and most of the reptiles and most of other things
as well. But in the Permian, there was quite an ecosystem of reptiles, which were distant cousins
of mammals. There were herbivores and carnivores, a whole ecosystem called the therapsids, which aren't
therapists or either theropsids, which are different. Don't talk to me about theropsids.
But most of these were wiped out in the extinction. What happened after the extinction was a bit
like what happens on a bomb site, a bomb site or anywhere where there's been a catastrophe.
is soon colonised by what's called a disaster assemblage.
When you look at old bomb sites or building sites,
you see the same plants, you know, like red-hot pokers
and ferns and brambles and stuff.
And these colonise things really quickly.
Well, there was the same thing after the end permanent extinction,
only on a bigger scale.
Immediately after the end permanent extinction,
nine out of ten animals was one kind of animal called lystrosaurus,
which was one of these distant cousins of mammals.
But these were happy go lucky, go anywhere, eat anything animals.
I was trying to describe them.
They were different kinds of lystrosaurus.
Some were quite small, like, you know, cat size.
Some were as big as hippos.
But they were different kinds of lystros.
Because there are no pictures in the book.
It's a very small book.
I'm having to paint the pictures with words.
So I described them as having the body of a pig
and the eat-any-thing attitude of a goldener
and the head of an electric can opener.
So they had this kind of blade at the front and little teeth that they just shoveled anything
in.
In the earliest Triassic, which was after the catastrophe, they lived everywhere.
They lived in jungles.
They lived in swamps.
They lived in deserts.
They ate anything and lived in burrows, which was probably a good way to keep out of catastrophe.
And the only other animals that survived used to sort of share lystrosaurus burrows.
and from Leicestersaurus
and the few other animals that survived
came all the animals we know today
and in the sea as well was the same
a lot of the ancient sea life
the last trilobites died out
in that catastrophe for example
so we don't see any more of those
and all sorts of peculiar animals
that we don't see any more died out
but on the land in the Triassic period
that was a great big raspberry
to the earth
I can do a raspberry now like this
well imagine that in terms
of evolution, because the Triassic period was the most amazing carnival of land life that
has ever been. Lots of amazing kinds of reptiles with unpronounceable names evolved in the sea
on land. Some of them were really, really odd. Many of them took to the air. There was this really
strange creature called Sharavipteryx, which had wings, but not on its front legs, on its hind legs.
Its front legs were just little sticking out of the front. And there were really weird creatures
that we have no analogue of today,
that they all lived and died in the Triassic.
It was a real carnival of diversity.
And amid all this diversity,
several other new animals evolved.
There were turtles,
but these were very, very varied.
There were turtles that had plates on their belly,
but no shells.
There were turtles that had shells and belly plate.
There were turtles that didn't really have any shell plates or belly plates,
but had a turtle-like beak.
So there were turtles, pretend turtles, mock turtles.
wannabe turtles and teenage mutant ninja turtles.
And they all lived together in the Traasic
and the only turtles we have today,
are the ones still with us.
The first true frogs evolved in the Traassic period.
And so did the mammals
from a distant cousin of Leicrosaurus.
There were little carnivores called synodons
and they specialized in being small
with active metabolisms.
The early cyndons were quite big
but they got smaller from large dogs to small dogs
to cats to weasels to mouse to shrews.
And as they got smaller, they got furrier and more and more nocturnal.
And they just lived in all the nooks and corners for a long time and nobody noticed them.
And, of course, the other group of animals that evolved in the Triassic is everyone's favorite prehistoric animals, the dinosaurs.
So I'm going to have a glass of water now and you're going to ask me about dinosaurs.
Well, Henry, we might have to save dinosaurs in debt for another podcast, but I will ask one question before we wrap up about them, of course.
Interesting, you mentioned their synodons.
I remember watching walking with dinosaurs
when I was very young.
And synodons, I think they feature
in that Triassic episode
is one of the small mammals.
Yes, they do.
Mammals did evolve alongside the dinosaurs,
but they were mostly very small.
But in the way that sea animals
saw the land as a new opportunity
where nothing,
the mammals found an entirely new place to live in
that no other large animals were colonising.
That was the night.
So they became small.
They became warm-blooded.
and they chased insects
and they weren't very good at seeing
but they had whiskers and fur
and a very good sense of smell and touch
and hearing.
Mammals evolved a marvellous sense of hearing
by a complete accident of the way their jaws were structured
because all their jaw bones
as they got smaller a lot of the bones at the back of the jaw
got squeezed backwards to where the middle ear happens
and they became the bones of the middle ear
and that allowed mammals to hear much higher frequencies than other animals.
And it revealed to them an entire sensory universe that was previously close to them.
They could hear the high-pitched squeaks of insects that they could capture.
They could squeak to each other so high-pitched that no other animals could hear this private communication.
And mammals made the night their own for 160 million years.
While the dinosaurs were busy stomping around in the daytime and bumping into each other,
the mammals were keeping well out of the way, waiting for their time to come.
Well, Henry, talk to us a bit about these early dinosaurs of the Triassic then.
We'll talk in more depth about dinosaurs in the future pod, I've no doubt,
because that'd be great to focus in on...
Yeah, it would, because there's lots more to say.
Well, exactly. Give us a taster, therefore, these early dinosaurs.
Well, in the Triassic, there were lots and lots of amazing kinds of reptiles of all kinds,
and a lot of them were kind of vaguely crocodile-y.
And there were some things that actually did look like crocodiles.
They lived on four stumpy legs and had armour and lived in the sea.
And not lived in, well, some of them did live in the sea,
lived on land and looked much like crocodiles.
But there were some crocodile-like animals
that actually evolved to live on their hind legs
and evolved a kind of bipedal locomotion
where their whole fulcrum was concentrated over the hips.
So they had a short body forward of the hips
and a long tail,
counterbalanced it, and that made them really maneuverable. Now, there were many kinds of crocodile-like
animal that were like that in the Triassic, but there was this one lineage of the dinosaurs. Now,
they evolved in the last third of the Triassic, but they lived alongside a lot of animals that
were more or less like them, but they weren't the main event. They were like the second violins
in the reptile orchestra behind the star soloists, but in front of the French horns and the timpani.
they were okay, but they only lived in certain parts of Gondwana land and northern Pangea.
But as the Triassic progressed and some of the other herbivores and carnivores declined,
dinosaurs quietly slotted in to take their place.
So by the end of the Triassic, there were all the familiar dinosaurs that we know about,
the big gigantic sauropods and the small fierce theropods, which eventually,
and things like T-Rex and Brachosaurus.
But that was a long away.
There was another great extinction at the end of the Triassic
because Pangea had started to drift apart.
There was a rift.
A giant Rift Valley happened in what is now North America
along the Appalachian mountain front,
which is a kind of weak point in the earth.
That part of North America keeps sticking together
and keeps moving apart.
It had done so in the past.
So a huge Rift Valley, like a gash in the earth,
opened between the Carolinas in the south to the Bay of Fundy,
stripping apart eastern North America from what was then North Africa, which was joined to it.
And that produced lots of the usual volcanoes and carbon dioxide and the usual fuss and mess and disaster,
and created the Atlantic Ocean.
So this was Pangaea starting to drift apart.
So the end Triassic extinction was like the third or fourth most intense mass extinction
in the Earth's recent history.
and that wiped out a lot of animals
including a lot of the
fantastic triassic reptiles
but the dinosaurs by luck
survived
and so for the Jurassic and Cretaceous
they had the world to themselves
with all the little mammals scarring around
under their feet trying not to be trodden on
prudence well we will delve into that
in more detail in due time
like the Jurassic the Cretaceous
amazing can't wait to talk about those
but finally as we wrap up
Henry, looking at this topic. And of course, today we've climate change, at global warming,
right at the forefront of things, looking at the beginning of life, looking at all of these
events, these natural events. What lessons can we learn from this for today?
I think what it's given me when I've written the book is to take a very long view of current
events. I no longer listen to the news much. I'd rather listen to you talking about ancient
history because I think one of the great disasters of the media is the 24-hour news cycle.
Everything is so short term. But when you look at the long term, the earth has been subjected
to cataclysm and life has always recovered. Now, climate change caused by human beings is
absolutely real and is absolutely urgent. But it's happened very, very recently. I mean,
within the last 500 years at most, and in fact, most intensely in the last 2 to 300 during the
industrial revolution, and perhaps mostly in the last hundred because of the internal combustion
engine. But all these things are passing things, and it's not true to say that people haven't
been doing anything about it because people have, whether it's by the forces of the market,
because people choose to live more sustainably. But this has been happening for a long time,
I mean, in historical terms, people no longer drive those big gas-guzzling cars anymore, and they
haven't for a long time. And the internal combustion engine, in the internal combustion engine,
invented in 1876, will be a thing of the past in about 20 years time. The internal combustion
will still be there, but it'll be as antique as manual typewriters. I mean, they're still there,
but they're only kind of niche. So people are beginning to do things about it. Also, a lot of
it's been driven by human population growth, and that's beginning to slow down, partly because
of increases in health and welfare. And the biggest change in the past hundred years has been the
political and reproductive emancipation of women, which has only happened in the past hundred
years. And because of that, women are now part of the workforce and can choose when to reproduce.
Now, for all of the history of animals, females would become pregnant as soon as they were able
and keep having babies until they couldn't do it anymore. And that was true until quite recently.
But now it isn't. And because of that, the population is coming down, or at least it's still
going up, but it's going up more slowly. And all sorts of wonderful things.
have flowed from female emancipation, longevity, health, welfare, education. So there are a lot of good
things to say. Like in 1970, only one in five people in the earth completed primary education.
Now it's one in two. And it'll be everyone in the whole world, not just in what we patronisingly
call the developed world. It'll be everywhere by 2030. And the population will peak in the 26th
and then start to go down quite rapidly.
So human beings will become extinct in the next few tens of thousands of years,
but we can manage that decline.
And as part of that, we can manage amelioration of climate.
There will be changes.
There will be flooding.
There will be widespread migrations and a lot of problems and disasters.
But these are economic and governmental.
We are not seeing the sixth mass extinction that people have talked about.
We are going that way,
but only if we keep doing what we've been doing for another five,
500 years. And people are already pulling back. They're already success stories in conservation.
People are already knowing what to do. And the great thing about human beings is that human beings
are the only species in their history of the earth, as far as we know, that are actually
conscious of what we're doing. I mean, the little bacteria that released huge amounts of
lethal oxygen into the earth's atmosphere killing virtually everything, you know, two and a half
billion years ago, they presumably didn't know what they were doing. And yet they caused probably
the biggest mass extinction of all time. But we do know what we're doing. And we're doing. And we're
doing something about it. And the problem is urgent and pressing, and it's very, very right that
people are drawing attention to it. And the governments are falteringly, haltingly, not very well
making promises, but they are going in that direction. The human cause spike in carbon
dark side is a bit like a tiny version of the end perm in extinction. You know, it's very, very
brief. The carbon dioxide in the atmosphere now is higher than it's been for hundreds of
thousands of years, but it won't last long. It'll be very, very brief.
it'll be a spike, and then things will carry on.
So I'm cautiously optimistic about the future,
but then being a paleontologist,
I'm cautiously optimistic over hundreds of thousands of years.
I mean, the next century is going to be quite difficult for a lot of people,
but I think we'll already have the tools to manage it.
As the science fiction writer, William Gibson once said,
the future is already here.
It's just not widely implemented.
So I think these are the lessons to do.
draw is that the Earth is very resilient. We don't need to save the planet. The planet will quite
happily carry on and could wipe out the whole of life if it wanted, if it were a thinking being.
What we need to do is save ourselves because the Earth is always changing and what we need to do is
be conservative with a small sea and try and work to maintain our level of comfort and luxury
and learn how to manage the changes to come in a way that is equitable and comfortable.
for the greatest number of people.
So I'm not one of these people
who goes around preaching doom and gloom
because I think there is a way out of it
and the human beings will disappear in due course
and the earth will just carry on.
But we can manage things with a bit of goodwill.
It can be done.
Climate change is absolutely real.
It's really a big threat.
But it's not the end of the world.
That's a much bigger deal.
Well, there you go. There was a throwback to our first ever episode with Dr. Henry G. covering the origins of life on Earth. You can listen to Part 2 of that interview now. We recorded that in the last few months. It's just gone out. And that episode is titled The Age of Dinosaurs, where we go from the beginning of dinosaurs, right through to the end. Thank you for listening to this episode of The Ancients. Please follow the show on Spotify or wherever you get to your podcasts. That really helps us, and you'll be doing us a big favor.
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That's all from me, and I'll see you in the next episode.