Wonders of Life (2013–…): Season 1, Episode 4 - Size Matters - full transcript
Professor Brian Cox travels to Australia, the big country down under, to explain how size determines the nature of life. Gravity and electromagnetism impact heavily on different types of life - from a single bacterium to a 110 meter tree - determining shape, movement and longevity.
Our world is covered in giants.
The largest things that ever lived
on this planet
weren't the dinosaurs.
They're not even blue whales.
They're trees.
These are Mountain Ash, the largest
flowering plant in the world.
They grow about a metre a year
and these trees are 60, 70,
even 80 metres high.
But to get this big,
you need to face some very
significant physical challenges.
These giants can live
to well over 300 years old.
But they don't keep
growing forever.
There are limits to how big
each tree can get.
As with all living things,
the structure,
form and function of these trees
has been shaped by the process of
evolution through natural selection.
But evolution doesn't have a
free hand.
It is constrained by the universal
laws of physics.
Each tree has to support its mass
against the downward
force of Earth's gravity.
At the same time,
the trees rely on the strength
of the interactions
between molecules to raise
a column of water from the ground
up to the leaves in the canopy.
And it's these fundamental
properties of nature
that act together to limit the
maximum height of a tree,
which theoretically lies somewhere
in the region of 130 metres.
With its forests and mountains...
Oceans and deserts...
I've come to Australia to explore
the scale of life's sizes.
I want to see how the
laws of physics
govern the lives
of all living things.
From the very biggest...
to the very smallest.
The size of life on Earth
spans from the tallest tree,
over 100 metres tall and with
a mass of over 1,000 tonnes,
to the smallest bacterium cell,
with a length less than
a millionth of a millimetre
and a mass less than a million
millionths of a gram.
And that spans over 22 orders
of magnitude in mass.
I want to see how size influences
the natural world.
How do the physical forces of nature
dictate the lives of the big
and the small?
Do organisms face different
challenges at different scales?
And do we all experience the world
differently, based on our size?
The size you are
profoundly influences the way
that you live your life.
It selects from the properties
of the natural world
that most affect you.
So, I suppose that whilst
we all live on the same planet,
we occupy different worlds.
I'm heading out to
the Neptune Islands,
west of Adelaide in South
Australia...
in search of one of nature's
largest killing machines.
These beasts are feared
around the world,
a fear not helped
by Hollywood filmmakers.
I'm here to swim
with great white sharks.
ENGINE STARTS UP
How big... How wide can they
open their jaw? Three foot wide.
About three feet.
They can swallow a man whole. Yes.
So about three...
Three foot wide,
can swallow a man whole.
The skipper has a special permit
to use bait to lure the sharks in.
The crew ready the cages.
The last time I dived
was in the marina in Brighton.
I did see a fish.
It was about that big.
From that to the largest
marine predator.
CLEARS HIS THROAT
As the sharks start to circle,
it's time to get in.
There he is. There he comes.
Just look at that.
He's just checking us out.
Well, he's turning straight for us.
Look at those teeth.
Graceful, elegant thing.
Shaped by natural selection.
Brilliant at what it does,
which is to eat things.
HE LAUGHS
Well, I never would've thought you
could be that close to one of those.
Great whites are highly evolved
predators.
Around two thirds of their brain is
dedicated to their sense of smell.
They can detect as little as one
part per million blood.
In this water, the tiniest
speck of blood...
will attract the shark.
These fish can grow to a huge size.
But still move with incredible speed
and agility.
They've been
sculpted by evolution,
acting within the bounds
of the physical properties of water.
Now, he's about five metres long.
He weighs about a ton.
And he's probably the most
efficient predator on earth.
When he's attacking,
he can accelerate up to
over 20 miles an hour.
They can launch themselves
straight out of the water.
There he is! There he is.
Whoa!
Whoa!
I felt the need to remove my hands.
That was one of the most
awe-inspiring sights I've ever seen.
A great white, just straight
in front of me with its mouth open.
With the boat moored up,
away from shark-infested waters,
I want to explore why
it's in our oceans that we find
the biggest animals on Earth.
From giant sharks to blue whales,
the largest animals that have ever
lived have lived in the sea.
The reason why is down to physics.
This is a container
full of saltwater
and I'm going to weigh it.
You see, that says
25 kilograms there.
That's actually its mass.
Its weight is the force the Earth
is exerting on it due to gravity,
which is 25 times about ten,
which is 250 kilogram metres
per second squared.
That might sound pedantic, but it's
going to be important in a minute.
See what happens if I lower
this saltwater into the ocean.
Its weight has effectively
disappeared. It's effectively zero.
Now, of course, gravity
is still acting on this thing,
so by the strictest sense
of the word,
it still has the same weight
as it did up here,
but Mr Archimedes told us
that there's another force
that's come into play.
There's a force proportional
to the weight of water
that's been displaced by this thing
and because this thing
has essentially the same density
as seawater,
because it's made of seawater,
then that force is equal and
opposite to the force of gravity,
and so they cancel,
so it's effectively weightless
and that is extremely
important indeed
for the animals
that live in the ocean.
The cells of all living things are
predominantly made up of salty water
so in the ocean,
weight is essentially unimportant.
Because of Archimedes' principle,
the supportive nature of water
releases organisms from
the constraints of Earth's gravity,
allowing the evolution
of marine leviathans.
But this comes at a cost.
Water is 800 times denser than air
and so whilst it provides support,
it requires a huge amount of effort
to move through it.
Not only does the shark have to
push the water out of the way,
it also has to overcome drag forces
created by the frictional contact
with the water itself.
The solution for the shark
lies in its shape.
If you look at him,
that great white,
he's got that distinctive
streamlined shape.
His maximum width is about
a third of the way down his body,
and that width itself should be
around a quarter of the length.
That ratio is set by the necessity
for something that big
to be able to swim effectively
and quickly through this medium.
This shape reduces
drag forces to a minimum
and optimises the way
water flows around the shark's body.
It is the result of evolution,
shaped by the laws of physics.
Whoa!
HE LAUGHS
That's cunning!
That was straight out of Jaws!
That streamlined shape of a shark
is something that you see
echoed throughout nature.
I mean, think of a whale
or a dolphin or a tuna,
all that same torpedo-like shape,
and that's because they're
contending with problems that arise
from the same laws of physics
and convergent evolution has
driven them to the same solution.
For life in the sea, the evolution
of giants is constrained
directly by the physical
properties of water.
But out of the ocean,
life now has to content with
the full force of Earth's gravity.
And it's this force of nature
that dominates the lives
of giants on land.
This is the hot, dry outback north
of Broken Hill in New South Wales.
I'm here to explore how gravity,
a force whose strength is governed
by the mass of our whole planet,
moulds, shapes and ultimately
limits the size of life on land.
I've come to track down one of
Australia's most iconic animals...
..the red kangaroo.
Red kangaroos are Australia's
largest native land mammal,
one of 50 species of macropods,
so-called on account
of their large feet.
(WHISPERS) There! There.
There's two very close there.
The kangaroos are the
most remarkable of mammals
because they hop.
There's no record,
even in the fossil record,
of any other large animal
that does that
but it makes them
very fast and efficient.
When Joseph Banks,
who's one of my scientific heroes,
first arrived here with Captain
Cook on the Endeavour in 1770,
he wrote that "They move so fast
"over the rocky, rough ground
where they're found,
"even my greyhound
couldn't catch them."
I mean, what was he doing
with a greyhound?
Kangaroos are herbivorous
and scratch out a living
feeding on grasses.
While foraging,
they move in an ungainly fashion,
using their large, muscular tail
like a fifth leg.
But when they want to,
these large marsupials can cover
ground at considerable speeds.
To take a leap,
kangaroos have to work against the
downward pull of Earth's gravity.
This takes a lot of energy.
As animals go faster,
they tend to use more energy.
Not so with the kangaroos.
As the roos go faster, their energy
consumption actually decreases.
It then stays constant,
even at sustained speeds of
up to 40 kilometres per hour.
This incredibly efficiency
for such a large animal
comes directly from
the kangaroos' anatomy.
Kangaroos move so efficiently
because they have an ingenious
energy storage mechanism.
See, when something hits the ground
after falling from some height,
then it has energy
that it needs to dissipate.
If you're a rock...
..that energy is dissipated
as sound and a little bit of heat
but if you're a tennis ball...
..then some of that energy is reused
because a tennis ball is elastic,
it can deform, spring back,
and use some of that energy to throw
itself back into the air again.
Well, a kangaroo is very similar.
It has very elastic tendons
in its legs,
particularly its Achilles tendon
and also the tendons in its tail,
and they store energy
and then they release it,
supplementing the power
of the muscles
to bounce the kangaroo
through the air.
Now, an adult kangaroo
is 85, 90 kilos,
which is heavier than me,
and when it's going at full speed,
it can jump around nine metres.
That's the distance from me...
..to that car.
The evolution of the ability to hop
gives kangaroos a cheap
and efficient way to move around.
But not everything
can move like a kangaroo.
The red kangaroo is the largest
animal in the world
that moves in this unique way,
hopping across the landscape
at high speed,
and there are reasons why there
aren't giant hopping elephants
or dinosaurs, and
they're not really biological,
it's not down to
the details of evolution
by natural selection
or environmental pressures.
The larger an animal gets,
the more severe the restrictions
on its body shape and its movements.
To understand why this is the case,
I want to explore what happens
to the mass of a body
when that body increases in size.
Take a look at this block.
Let's say it has width - one,
length - one, and height - one,
then its volume is one
multiplied by one multiplied by one,
which is one cubic...
things, whatever the measurement is.
Now, its mass is proportional
to the volume,
so we could say that the mass
of this block is one unit as well.
Let's say that we're going to
double the size of this thing
in the sense that we want to
double its width,
double its length,
double its height.
Then its volume is two
multiplied by two multiplied by two,
equals eight cubic things.
Its volume has increased
by a factor of eight,
and so its mass has increased
by a factor of eight as well.
So although I've only doubled
the size of the blocks,
I've increased the total mass
by eight.
As things get bigger,
the mass of a body goes up by
the cube of the increase in size.
Because of this scaling
relationship,
the larger you get,
the greater the effect.
As things get bigger,
the huge increase in mass
has a significant impact
on the way large animals
support themselves against gravity
and how they move about.
No matter how energy-efficient
and advantageous it is
to hop like a kangaroo,
as you get bigger,
it's just not physically possible.
Going supersize on land comes with
tremendous constraints attached.
This is the left femur,
the thigh bone
of an extinct animal
called a Diprotodon,
which is the largest known marsupial
ever to have existed.
This would have stood as tall as me,
it would have been four metres long,
weighed between two and
two-and-a-half tons,
so the size of a rhino,
and it's known that
it was all over Australia,
it was the big herbivore,
and it got progressively bigger
over the 25 million years
that we have fossils for it,
and then around 50,000 years ago,
coincidentally,
when humans arrived in Australia,
the Diprotodon became extinct.
The Diprotodon is thought to
have looked like a giant wombat
and being marsupials, the females
would have carried their sheep-sized
offspring in a huge pouch.
To support their considerable bulk,
the Diprotodon skeleton
had to be very strong.
This imposed significant constraints
on the shape and size of its bones.
This is the fever of the closest
living relative of the Diprotodon.
It's a wombat, which is an animal
around the size of a small dog.
And you see that superficially,
the bones are very similar.
But let me take a few measurements.
The length of the Diprotodon femur
is...what, around 75 cm.
The length of the wombat femur
is around 15 cm,
so this is about five times
the length of the wombat femur.
But now look at
the cross-sectional area.
Assuming the bones are roughly
circular in cross-section,
we can calculate their area using
pi multiplied by the radius squared.
It turns out that
although the Diprotodon femur
is around five times longer,
it has a cross-sectional area
40 times that of the wombat femur.
A bone's strength depends directly
on its cross-sectional area.
The Diprotodon needed thick leg
bones, braced in a robust skeleton,
just to provide enough strength to
support the giant's colossal weight.
As animals get more massive,
the effect of gravity
plays an increasingly restrictive
role in their lives.
The shape and form of their body
is forced to change.
If you look across the scale
of Australian vertebrate life,
you see a dramatic difference
in bone thickness.
This is a line of femur bones
of animals of different sizes.
We start with the smallest,
one of the smallest
marsupials in Australia,
the marsupial mouse
or the Antechinus.
Then the next one is
an animal known as the Potoroo.
Again, it's a marsupial
around about the size of a rabbit.
Then we have the Tasmanian Devil,
a wombat,
a dingo,
then the largest marsupial
in Austria today,
the red kangaroo.
And this is the femur
of the Diprotodon
and then, here,
the femur of a Rhoetosaurus,
which was a sauropod dinosaur
17 metres long
and weighing around 20 tons.
And so, you see,
as animals get larger,
from the smallest marsupial mouse,
all the way up to a dinosaur,
the cross-sectional area of
their bones increases enormously,
just to support that increased mass.
Being big and bulky,
giants are more restricted
as to the shape of their body
and how they get about.
That's why red kangaroos
are the largest animals that can
move in the way that they do.
At a much greater size,
their bones would be very heavy,
have a greater risk of fracture,
and they'd require far too much
energy to move at high speeds.
It's ultimately
the strength of Earth's gravity
that limits the size
and the manoeuvrability
of land-based giants.
But for the bulk of life on land,
gravity is not
the defining force of nature.
At small scales, living things
seem to bend the laws of physics,
which is, of course, not possible.
The world of the small
is often hidden from our view,
but there are ways
to draw out these tiny creatures.
This is the domain of the insects.
These animals can clearly
do things I can't do
and appear to have superpowers.
They can walk up walls,
jump many times their own height,
and can lift many times
their own weight.
There are over 900,000 known
species of insects on the planet.
That's over 75%
of all animal species.
Some biologists think that
there may be an order of magnitude
more yet to be discovered.
That would be ten million species,
and they're very small,
so you can fit a lot of them
on Planet Earth at any one time.
In fact, it's estimated there are
over ten billion billion
individual insects alive today.
Of all the insect groups,
it's the beetles, or coleoptera,
that have
the greatest number of species.
The biologist JBS Haldane said that
if one could conclude as
to the nature of the Creator
from a study of creation,
then it would appear that
God has an inordinate fondness
for stars and beetles.
With so much variation
in colour, form and function,
beetles have fascinated
naturalists for centuries.
Each species is wonderfully adapted
to their own unique niche.
This is the beginnings of biology
as a science that you see here,
it's this desire
to collect and classify,
which then, over time, becomes the
desire to explain and understand.
I'm going to take a picture.
Here in the suburbs of Brisbane,
every February,
there's an invasion of beetles.
The rules governing their lives
play out very differently to ours.
This is the Rhinoceros Beetle,
named for obvious reasons.
But actually, it's only the males
that have the distinctive horns
on their heads.
These beetles spend much of their
lives underground as larvae,
but then emerge en masse
as adults to find a mate and breed.
Much of this time, the males
spend fighting over females.
See that distinctive posture
that he's adopting there?
That's because I think
he's seeing his reflection in
the camera lens, and so he rears up.
Look at that! He's trying to scare
himself off.
Ha-ha-ha!
INSECT BRISTLES
You also heard that hissing sound.
That's him contract in his abdomen
which again is a defensive
posture that he adopts to scare
other males.
INSECT HISSES
Gramme for gramme, these insects are
among the strongest animals alive.
I can demonstrate that I just
getting hold of the top of his head.
It doesn't hurt him at all,
but watch what he is able to do.
Look at that.
So he is hanging on to this branch,
which is many times his own
bodyweight.
Absolutely no distress at all.
As things get smaller, it is
a rule of nature that they
inevitably get stronger.
The reason is quite simple.
Small things have relatively large
muscles compared
to their tiny body mass
and this makes them very powerful.
The beetles also appear to have a
cavalier attitude to
the effects of gravity.
They fight almost like
sumo wrestlers,
their aim is to throw each
other off the branch.
If they should fall...
they just bounce and walk off.
If I fail a similar distance
relative to my size, I'd break.
So why does size make
such a difference?
Time for a bit
of fundamental physics.
All things fall at the same rate
under gravity.
That's because they they're
following geodesics
through curved space-time,
but that's not important.
The important thing for biology is
that although everything falls at
the same rate, it doesn't meet the
same fate when it hits the ground.
A grape bounces.
A melon...
Doesn't bounce.
The reasons for that are quite
complex actually.
First of all, the grape has a larger
surface area in relation
to its volume and therefore its
mass than the melon.
Although, in a vacuum,
if you took away the air,
they would both fall at the same
rate. Actually, in reality,
the grape falls slower
than the melon.
Also, the melon is more massive
so it has more kinetic energy
when it hits the ground.
Remember physics class.
Kinetic energy is
½ MV squared,
so you reduce M,
you reduce the energy.
The upshot of that is that the melon
has a lot more energy
when it hits the ground.
It has to dissipate it in some way
and it dissipates it by exploding.
The influence of Earth's gravity
in your life becomes progressively
diminished the smaller you get.
For life at the small scale,
a second fundamental
force of nature starts to dominate.
And it's this that explains
many of those apparent superpowers.
For me, the force of gravity is
a thing that defines my existence.
It's the force that
I really feel the effects of.
But there are other forces at work.
For example if I lick my finger
and wet it, I can pick up a piece
of paper and can hold up against the
downward pull of gravity.
That's because the force
of electromagnetism is important.
In fact, it is the cohesive forces
between water molecules
and the molecules that
make up my finger
and the molecules that make
up the paper,
that are dominating this
particular situation.
That's why this piece
of paper doesn't fall to the floor.
Many insects can use
a similar effect.
Take a common fly for example.
Their feet have especially
enlarged pads onto which
they secrete a sticky fluid.
And that allows them
to adhere to rather slippery
surfaces like the glass of this
jam jar.
It allows them to do things that for
me would be absolutely impossible.
It's all down to the relative
influence of the different
forces of nature on the animal.
So the capacity to walk up walls
and fall from a great height without
breaking, plus supers trength,
are not super powers at all.
They're just abilities gained
naturally by animals
that are small and lightweight.
But this is just the beginning of my
journey into the world of the small.
Down at the very small scale,
it becomes possible to live
within the lives of other
individuals, worlds within worlds.
But just how small can animals get?
This macadamia nut plantation,
an hour outside of Brisbane,
is home to one of the very smallest
members of the animal kingdom.
These are a species
of micro-hymenoptera
known as Trichogramma.
They're basically very small wasps
and when I say small,
I mean small.
Can you see that?
They're like specks of dust.
They're less than half
a millimetre long,
but each one of those is a wasp.
It's got compound eyes,
six legs and wings.
They've even got a little
stripe on their abdomen.
And they're very precisely adapted
to a specific evolutionary niche.
The Trichogramma wasps may be
small, but they're very useful.
Theyr're natural parasites of an
insect pest species
called the nut borer moth which
attacks the macadamia nuts.
The micro-wasps lay their eggs
inside the eggs of the moths,
killing the developing moth larvae.
What you're seeing here is
the surface of the macadamia nut
and here's a small cluster of moth
eggs and there,
you see the wasp is walking
over the eggs.
They're almost
pacing out the size to see
whether the eggs are suitable
for their eggs to be laid inside.
And if we're lucky, there you go,
you see that...
That...
There we go.
The wasps emerge just nine days
later as full-grown adults.
At this scale,
they live a very sticky world,
dominated by strong
intermolecular forces.
To them, even the air is a thick
fluid through which
they essentially swim,
using paddle-like wings.
Incredibly, these tiny animals can
move about across several trees,
seeking out the moth eggs.
But what I find more remarkable
is that they do all this operating
with very restricted brain power.
One of the limiting factors that
determines the minimum
size of insects is the volume
of their central nervous system.
In other words, the processing power
you can fit inside their bodies
and these little wasps are pretty
much at their limit.
They've less than 10,000 neurons
in their whole nervous system.
To put it into perspective,
most tiny insects have 100 times
that many, but that's still
enough to allow them
to exhibit quite complex behaviour.
These micro-wasps exist at almost
the minimum possible size
for multicellular animals.
But the scale of life on our planet
gets much, much smaller.
The wasps are giants
compared to life at the very limit
of size on earth.
The smallest organisms on our
planet are also our oldest
and most abundant type of lifeforms.
These weird, rocky blobs
in the shallows of Lake Clifton,
just south of Perth,
are made by bacteria.
These mounds are called
thrombolites,
on account of their clotted
structure,
and they're built up over centuries
by colonies of microscopic
bacterial cells.
Although these colonies are rare,
by most definitions,
bacteria are THE dominant
form of life on our planet.
On every surface across every
landscape, you find bacteria.
In fact, numerically speaking,
then there are more bacteria
living on and inside my body
than there are human cells.
Bacteria come in many shapes
and forms
and are not actually
animals or plants,
instead sitting in their own
unique taxonomic kingdom.
Compared to the cells
we're made of,
bacteria are structurally much
simpler and far, far smaller.
Bacteria are typically
around two microns in size.
That's two millionths of a metre,
which is very hard to picture
but it means that you could fit
around half a million of them
on the head of a pin or,
to look at it another way,
if I took a single bacterium
and scaled it up to
the size of this coin,
then I would be 25 kilometres high.
SPLASH
Bacterial-type organisms were
the first life on Earth
and they've dominated our planet
ever since.
Excluding viruses, which by most
definitions are not alive,
bacteria are the smallest
free-living lifeforms we know of.
But what ultimately puts the limit
on the smallest size of life?
Single-cell life needs to be big
enough to accommodate all
the molecular machinery of life
and that size ultimately depends
on the basic laws of physics.
It depends on the size
of molecules which
depends on the size of atoms
which depends on fundamental
properties of the universe
like the strength of the force
of electromagnetism
and the mass of an electron.
And when you do those calculations,
you find out that the minimum size
of a free-living organism
should be around 200 nanometres
which is around 200 billionths
of a metre.
And that should be universal,
it shouldn't only apply
to life on Earth
but it should apply to any
carbon-based life
anywhere in the universe
because it depends on fundamental
properties of the universe.
From the smallest bacterium
to the largest tree,
it's your size that determines
how the laws of physics
govern your life.
Gravity imposes itself on the large,
and the electromagnetic force
rules the world of the small.
But the consequences of scale
for life on Earth
extend beyond dictating the
relationship
you have with the world around you.
Your size also influences how energy
itself flows through your body.
BATS SQUEAK FAINTLY
These are southern bent-wing bats...
..one of the rarest
bat species in Australia.
Every evening, they
emerge in their thousands
from this cave, in order to feed.
When fully grown, these
bats are just 5.5cm long,
and weigh around 18 grams.
Because of their size, they face
a constant struggle to stay alive.
BATS SQUEAK, CRICKETS CHIRP
We're using a thermal camera
here to look at the bats,
and you can see that they
appear as streaks across the sky.
They appear as brightly as me -
that's because they're
roughly the same temperature as me.
They're known as endotherms -
animals that maintain
their body temperature.
And that takes a lot of effort.
These bats have
to eat something like
three-quarters of their
own body weight every night,
and a lot of that energy goes
into maintaining their temperature.
As with all living things,
the bats eat to provide energy
to power their metabolism.
Although, like us,
they have a high body
temperature when they're active,
keeping warm is a considerable
challenge, on account of their size.
The bats lose heat mostly through
the surface of their bodies.
But because of simple laws
governing the relationship
between the surface area
of a body and its volume,
being small creates a problem.
BATS SQUEAK
So, let's look at our blocks again,
but this time for
surface area to volume.
Here's a big thing -
it's made of eight blocks
so its volume is eight units,
and its surface area is two by
two on each side, so that's four,
multiplied by the six faces is 24.
so, the surface area to
volume ratio is 24 to eight,
which is 3:1.
Now, look at a smaller thing.
This is one block,
so its volume is one unit.
Its surface area is one by one
by one, six times, so it's six.
So, this has a surface
area to volume ratio of 6:1.
So, as you go from big to small,
your surface area
to volume ratio increases.
Small animals, like bats,
have a huge surface area
compared to their volume.
As a result, they naturally
lose heat at a very high rate.
To help offset the cost of losing
so much energy in the form of heat,
the bats are forced to
maintain a high rate of metabolism.
They breathe rapidly,
their little heart races,
and they have to eat a huge amount.
So, a bat's size clearly affects
the speed at which
it lives its life.
Right across the natural world,
the size you are has a profound
effect on your metabolic rate -
or your "speed of life".
EXTREMELY FAST HEARTBEAT
For Australia's
small marsupial mouse,
even at rest,
his heart is racing away.
SLOWER HEARTBEAT
For the fox-sized Tasmanian devil,
he ticks along
at a much slower rate.
And then there's me, living life
at a languid 60 beats a minute.
Looking beyond heart rate,
your size influences the amount
of energy you need to consume,
and the rate at which
you need to consume it.
Bigger bodies have
more cells to feed.
So, you might expect that the
total amount of energy needed
goes up at the same rate
as any increase in size.
But that's not what happens.
If you plot the amount of energy
an animal uses against its mass,
for a huge range of sizes,
from animals as small as flies,
and even smaller,
all the way up to whales,
then you DO get
a straight line, but the slope
is less than one. So, that implies
that gramme for gramme,
large animals use less
energy than small animals.
This relationship between
metabolism and size
significantly affects
the amount of food
larger animals have
to consume to stay alive.
Now, if my metabolic rate scaled
one-to-one with that of a mouse,
then I would need to eat about
four kilograms of food a day.
In my language, that's around
67,000 kilojoules of energy,
which more colloquially
is 16,000 calories.
That is eight times
the amount that I take in
on average on a daily basis.
Each of the cells in my
body requires less energy
than the equivalent cells
in a smaller-sized mammal.
The reason why this should be
so is not fully understood.
It's also not clear
whether this rule of nature
gives an advantage to big things,
or is actually a constraint
placed on larger animals.
Take the relationship between
an animal's surface area
and its volume.
Big animals have a much smaller
surface area to volume ratio
than small animals, and that means
that their rate of heat loss
is much smaller.
And that means that there's an
opportunity there for large animals.
They don't have to eat
as much food to stay warm,
and therefore they can afford
a lower metabolic rate.
Now this helps explain
the lives of large,
warm-blooded endotherms,
like birds and mammals,
but doesn't hold so well
for large ectotherms,
life's cold-blooded giants.
Now, there's another theory
that says that it wasn't really
an evolutionary opportunity
that large animals took
to lower their metabolic rate.
It was forced on them.
It was a constraint, if you like.
The capillaries,
the supply network to cells,
branches in such a way that
it gets more and more difficult
to get oxygen and nutrients
to cells in a big animal
than in a small animal.
Therefore, those cells must
run at a lower rate.
They must have
a lower metabolic rate.
Or it could just be
that as you get bigger,
then more of your mass is taken up
by the stuff that supports you,
and support structures,
like bones, are relatively inert.
They don't use much energy.
But whatever the reason,
it's certainly true to say
that the only way that large animals
can exist on planet Earth
is to operate at
a reduced metabolic rate.
If this wasn't the case,
the maximum size of a warm-blooded
endotherm like me or you
would be around that of a goat.
And cold-blooded animals,
or ectotherms like dinosaurs,
could only get as big as a pony.
Any bigger, and giants
would simply overheat.
Now, there's one last consequence
of all these scaling laws
that I suspect you'll care about
more than anything else,
and it's this -
there's a strong correlation
between the effective cellular
metabolic rate of an animal
and its lifespan. In other words,
as things get bigger,
they tend to live longer.
To explore this connection
between size and longevity,
I've left the mainland behind.
For my final destination,
I've come to one of Australia's
remotest outposts.
Named Christmas Island when it was
spotted on Christmas Day in 1643,
this isolated lump of rock in
the Indian Ocean is a land of crabs.
And in their midst lurks a giant
wonder of the natural world.
This is a Christmas Island
robber crab,
the largest land crab
anywhere on the planet.
These things can grow to around
50 centimetres in length,
they can weigh over four kilograms,
and they are supremely adapted
as an adult to life on land.
They can even climb trees.
Over the years,
the crabs have become
well adapted to human co-habitation.
These things are called robber crabs
because they have a reputation for
curiosity and for stealing things,
anything that isn't bolted down.
They'll steal food and cameras
if they can get half a chance.
These giants live on
a diet of seeds and fruit,
and occasionally other small crabs.
Their large, powerful claws mean
they can also rip open
fallen coconuts.
They're really quite a menacing
animal, actually, for a crab!
What's wonderful about these crabs
is that they live through
a range of scales.
At different times of their lives,
they have a completely
different relationship
with the world around them,
simply down to their size.
Throughout their lives, robber crabs
take on many different forms.
They begin their lives
as small larvae,
swept around by the ocean currents,
and as they grow,
some of them get swept up onto
the beaches of Christmas Island,
where they find a shell, because
they are, in fact, hermit crabs.
They live inside
their shell for a while,
they continue to grow,
and eventually, as adults,
they roam the forests
like this chap here.
So these crabs, over that lifespan,
inhabit many different worlds.
On land, the adults continue to grow
and now have to support
their weight against gravity.
Compared to the smaller crabs
whizzing around,
these giants move about
much more slowly,
but they also live far longer.
Of all the species of land crab
here on Christmas Island,
robber crabs are not only
the biggest,
they're also the longest-living.
So this chap here is probably
about as old as me,
and he might live
to 60, 70, even 80 years old.
Because of the robber crab's
overall body size,
its individual cells use less energy
and they run at a slower rate
than the cells of their much
smaller, shorter-lived cousins.
The pace of life is slower
for robber crabs,
and it's this
that's thought to allow them
to live to a ripe old age.
Your size influences
every aspect of your life...
..from the way you were built...
..to the way you move...
..and even how long you live.
Your size dictates how you interact
with the universal laws of nature.
So there's a minimum size,
which is set ultimately by
the size of atoms and molecules,
the fundamental building
blocks of the universe.
And there's a maximum size
which, certainly on land,
is set by the size and
the mass of our planet,
because it's gravity that restricts
the emergence of giants.
But within those constraints,
evolution has conspired to produce
a huge range in size
of animals and plants,
each beautifully adapted to exploit
the niches available to them.
Your size influences
your form and constriction.
It determines how you
experience the world,
and ultimately,
how long you have to enjoy it.
Subtitles by Red Bee Media Ltd
The largest things that ever lived
on this planet
weren't the dinosaurs.
They're not even blue whales.
They're trees.
These are Mountain Ash, the largest
flowering plant in the world.
They grow about a metre a year
and these trees are 60, 70,
even 80 metres high.
But to get this big,
you need to face some very
significant physical challenges.
These giants can live
to well over 300 years old.
But they don't keep
growing forever.
There are limits to how big
each tree can get.
As with all living things,
the structure,
form and function of these trees
has been shaped by the process of
evolution through natural selection.
But evolution doesn't have a
free hand.
It is constrained by the universal
laws of physics.
Each tree has to support its mass
against the downward
force of Earth's gravity.
At the same time,
the trees rely on the strength
of the interactions
between molecules to raise
a column of water from the ground
up to the leaves in the canopy.
And it's these fundamental
properties of nature
that act together to limit the
maximum height of a tree,
which theoretically lies somewhere
in the region of 130 metres.
With its forests and mountains...
Oceans and deserts...
I've come to Australia to explore
the scale of life's sizes.
I want to see how the
laws of physics
govern the lives
of all living things.
From the very biggest...
to the very smallest.
The size of life on Earth
spans from the tallest tree,
over 100 metres tall and with
a mass of over 1,000 tonnes,
to the smallest bacterium cell,
with a length less than
a millionth of a millimetre
and a mass less than a million
millionths of a gram.
And that spans over 22 orders
of magnitude in mass.
I want to see how size influences
the natural world.
How do the physical forces of nature
dictate the lives of the big
and the small?
Do organisms face different
challenges at different scales?
And do we all experience the world
differently, based on our size?
The size you are
profoundly influences the way
that you live your life.
It selects from the properties
of the natural world
that most affect you.
So, I suppose that whilst
we all live on the same planet,
we occupy different worlds.
I'm heading out to
the Neptune Islands,
west of Adelaide in South
Australia...
in search of one of nature's
largest killing machines.
These beasts are feared
around the world,
a fear not helped
by Hollywood filmmakers.
I'm here to swim
with great white sharks.
ENGINE STARTS UP
How big... How wide can they
open their jaw? Three foot wide.
About three feet.
They can swallow a man whole. Yes.
So about three...
Three foot wide,
can swallow a man whole.
The skipper has a special permit
to use bait to lure the sharks in.
The crew ready the cages.
The last time I dived
was in the marina in Brighton.
I did see a fish.
It was about that big.
From that to the largest
marine predator.
CLEARS HIS THROAT
As the sharks start to circle,
it's time to get in.
There he is. There he comes.
Just look at that.
He's just checking us out.
Well, he's turning straight for us.
Look at those teeth.
Graceful, elegant thing.
Shaped by natural selection.
Brilliant at what it does,
which is to eat things.
HE LAUGHS
Well, I never would've thought you
could be that close to one of those.
Great whites are highly evolved
predators.
Around two thirds of their brain is
dedicated to their sense of smell.
They can detect as little as one
part per million blood.
In this water, the tiniest
speck of blood...
will attract the shark.
These fish can grow to a huge size.
But still move with incredible speed
and agility.
They've been
sculpted by evolution,
acting within the bounds
of the physical properties of water.
Now, he's about five metres long.
He weighs about a ton.
And he's probably the most
efficient predator on earth.
When he's attacking,
he can accelerate up to
over 20 miles an hour.
They can launch themselves
straight out of the water.
There he is! There he is.
Whoa!
Whoa!
I felt the need to remove my hands.
That was one of the most
awe-inspiring sights I've ever seen.
A great white, just straight
in front of me with its mouth open.
With the boat moored up,
away from shark-infested waters,
I want to explore why
it's in our oceans that we find
the biggest animals on Earth.
From giant sharks to blue whales,
the largest animals that have ever
lived have lived in the sea.
The reason why is down to physics.
This is a container
full of saltwater
and I'm going to weigh it.
You see, that says
25 kilograms there.
That's actually its mass.
Its weight is the force the Earth
is exerting on it due to gravity,
which is 25 times about ten,
which is 250 kilogram metres
per second squared.
That might sound pedantic, but it's
going to be important in a minute.
See what happens if I lower
this saltwater into the ocean.
Its weight has effectively
disappeared. It's effectively zero.
Now, of course, gravity
is still acting on this thing,
so by the strictest sense
of the word,
it still has the same weight
as it did up here,
but Mr Archimedes told us
that there's another force
that's come into play.
There's a force proportional
to the weight of water
that's been displaced by this thing
and because this thing
has essentially the same density
as seawater,
because it's made of seawater,
then that force is equal and
opposite to the force of gravity,
and so they cancel,
so it's effectively weightless
and that is extremely
important indeed
for the animals
that live in the ocean.
The cells of all living things are
predominantly made up of salty water
so in the ocean,
weight is essentially unimportant.
Because of Archimedes' principle,
the supportive nature of water
releases organisms from
the constraints of Earth's gravity,
allowing the evolution
of marine leviathans.
But this comes at a cost.
Water is 800 times denser than air
and so whilst it provides support,
it requires a huge amount of effort
to move through it.
Not only does the shark have to
push the water out of the way,
it also has to overcome drag forces
created by the frictional contact
with the water itself.
The solution for the shark
lies in its shape.
If you look at him,
that great white,
he's got that distinctive
streamlined shape.
His maximum width is about
a third of the way down his body,
and that width itself should be
around a quarter of the length.
That ratio is set by the necessity
for something that big
to be able to swim effectively
and quickly through this medium.
This shape reduces
drag forces to a minimum
and optimises the way
water flows around the shark's body.
It is the result of evolution,
shaped by the laws of physics.
Whoa!
HE LAUGHS
That's cunning!
That was straight out of Jaws!
That streamlined shape of a shark
is something that you see
echoed throughout nature.
I mean, think of a whale
or a dolphin or a tuna,
all that same torpedo-like shape,
and that's because they're
contending with problems that arise
from the same laws of physics
and convergent evolution has
driven them to the same solution.
For life in the sea, the evolution
of giants is constrained
directly by the physical
properties of water.
But out of the ocean,
life now has to content with
the full force of Earth's gravity.
And it's this force of nature
that dominates the lives
of giants on land.
This is the hot, dry outback north
of Broken Hill in New South Wales.
I'm here to explore how gravity,
a force whose strength is governed
by the mass of our whole planet,
moulds, shapes and ultimately
limits the size of life on land.
I've come to track down one of
Australia's most iconic animals...
..the red kangaroo.
Red kangaroos are Australia's
largest native land mammal,
one of 50 species of macropods,
so-called on account
of their large feet.
(WHISPERS) There! There.
There's two very close there.
The kangaroos are the
most remarkable of mammals
because they hop.
There's no record,
even in the fossil record,
of any other large animal
that does that
but it makes them
very fast and efficient.
When Joseph Banks,
who's one of my scientific heroes,
first arrived here with Captain
Cook on the Endeavour in 1770,
he wrote that "They move so fast
"over the rocky, rough ground
where they're found,
"even my greyhound
couldn't catch them."
I mean, what was he doing
with a greyhound?
Kangaroos are herbivorous
and scratch out a living
feeding on grasses.
While foraging,
they move in an ungainly fashion,
using their large, muscular tail
like a fifth leg.
But when they want to,
these large marsupials can cover
ground at considerable speeds.
To take a leap,
kangaroos have to work against the
downward pull of Earth's gravity.
This takes a lot of energy.
As animals go faster,
they tend to use more energy.
Not so with the kangaroos.
As the roos go faster, their energy
consumption actually decreases.
It then stays constant,
even at sustained speeds of
up to 40 kilometres per hour.
This incredibly efficiency
for such a large animal
comes directly from
the kangaroos' anatomy.
Kangaroos move so efficiently
because they have an ingenious
energy storage mechanism.
See, when something hits the ground
after falling from some height,
then it has energy
that it needs to dissipate.
If you're a rock...
..that energy is dissipated
as sound and a little bit of heat
but if you're a tennis ball...
..then some of that energy is reused
because a tennis ball is elastic,
it can deform, spring back,
and use some of that energy to throw
itself back into the air again.
Well, a kangaroo is very similar.
It has very elastic tendons
in its legs,
particularly its Achilles tendon
and also the tendons in its tail,
and they store energy
and then they release it,
supplementing the power
of the muscles
to bounce the kangaroo
through the air.
Now, an adult kangaroo
is 85, 90 kilos,
which is heavier than me,
and when it's going at full speed,
it can jump around nine metres.
That's the distance from me...
..to that car.
The evolution of the ability to hop
gives kangaroos a cheap
and efficient way to move around.
But not everything
can move like a kangaroo.
The red kangaroo is the largest
animal in the world
that moves in this unique way,
hopping across the landscape
at high speed,
and there are reasons why there
aren't giant hopping elephants
or dinosaurs, and
they're not really biological,
it's not down to
the details of evolution
by natural selection
or environmental pressures.
The larger an animal gets,
the more severe the restrictions
on its body shape and its movements.
To understand why this is the case,
I want to explore what happens
to the mass of a body
when that body increases in size.
Take a look at this block.
Let's say it has width - one,
length - one, and height - one,
then its volume is one
multiplied by one multiplied by one,
which is one cubic...
things, whatever the measurement is.
Now, its mass is proportional
to the volume,
so we could say that the mass
of this block is one unit as well.
Let's say that we're going to
double the size of this thing
in the sense that we want to
double its width,
double its length,
double its height.
Then its volume is two
multiplied by two multiplied by two,
equals eight cubic things.
Its volume has increased
by a factor of eight,
and so its mass has increased
by a factor of eight as well.
So although I've only doubled
the size of the blocks,
I've increased the total mass
by eight.
As things get bigger,
the mass of a body goes up by
the cube of the increase in size.
Because of this scaling
relationship,
the larger you get,
the greater the effect.
As things get bigger,
the huge increase in mass
has a significant impact
on the way large animals
support themselves against gravity
and how they move about.
No matter how energy-efficient
and advantageous it is
to hop like a kangaroo,
as you get bigger,
it's just not physically possible.
Going supersize on land comes with
tremendous constraints attached.
This is the left femur,
the thigh bone
of an extinct animal
called a Diprotodon,
which is the largest known marsupial
ever to have existed.
This would have stood as tall as me,
it would have been four metres long,
weighed between two and
two-and-a-half tons,
so the size of a rhino,
and it's known that
it was all over Australia,
it was the big herbivore,
and it got progressively bigger
over the 25 million years
that we have fossils for it,
and then around 50,000 years ago,
coincidentally,
when humans arrived in Australia,
the Diprotodon became extinct.
The Diprotodon is thought to
have looked like a giant wombat
and being marsupials, the females
would have carried their sheep-sized
offspring in a huge pouch.
To support their considerable bulk,
the Diprotodon skeleton
had to be very strong.
This imposed significant constraints
on the shape and size of its bones.
This is the fever of the closest
living relative of the Diprotodon.
It's a wombat, which is an animal
around the size of a small dog.
And you see that superficially,
the bones are very similar.
But let me take a few measurements.
The length of the Diprotodon femur
is...what, around 75 cm.
The length of the wombat femur
is around 15 cm,
so this is about five times
the length of the wombat femur.
But now look at
the cross-sectional area.
Assuming the bones are roughly
circular in cross-section,
we can calculate their area using
pi multiplied by the radius squared.
It turns out that
although the Diprotodon femur
is around five times longer,
it has a cross-sectional area
40 times that of the wombat femur.
A bone's strength depends directly
on its cross-sectional area.
The Diprotodon needed thick leg
bones, braced in a robust skeleton,
just to provide enough strength to
support the giant's colossal weight.
As animals get more massive,
the effect of gravity
plays an increasingly restrictive
role in their lives.
The shape and form of their body
is forced to change.
If you look across the scale
of Australian vertebrate life,
you see a dramatic difference
in bone thickness.
This is a line of femur bones
of animals of different sizes.
We start with the smallest,
one of the smallest
marsupials in Australia,
the marsupial mouse
or the Antechinus.
Then the next one is
an animal known as the Potoroo.
Again, it's a marsupial
around about the size of a rabbit.
Then we have the Tasmanian Devil,
a wombat,
a dingo,
then the largest marsupial
in Austria today,
the red kangaroo.
And this is the femur
of the Diprotodon
and then, here,
the femur of a Rhoetosaurus,
which was a sauropod dinosaur
17 metres long
and weighing around 20 tons.
And so, you see,
as animals get larger,
from the smallest marsupial mouse,
all the way up to a dinosaur,
the cross-sectional area of
their bones increases enormously,
just to support that increased mass.
Being big and bulky,
giants are more restricted
as to the shape of their body
and how they get about.
That's why red kangaroos
are the largest animals that can
move in the way that they do.
At a much greater size,
their bones would be very heavy,
have a greater risk of fracture,
and they'd require far too much
energy to move at high speeds.
It's ultimately
the strength of Earth's gravity
that limits the size
and the manoeuvrability
of land-based giants.
But for the bulk of life on land,
gravity is not
the defining force of nature.
At small scales, living things
seem to bend the laws of physics,
which is, of course, not possible.
The world of the small
is often hidden from our view,
but there are ways
to draw out these tiny creatures.
This is the domain of the insects.
These animals can clearly
do things I can't do
and appear to have superpowers.
They can walk up walls,
jump many times their own height,
and can lift many times
their own weight.
There are over 900,000 known
species of insects on the planet.
That's over 75%
of all animal species.
Some biologists think that
there may be an order of magnitude
more yet to be discovered.
That would be ten million species,
and they're very small,
so you can fit a lot of them
on Planet Earth at any one time.
In fact, it's estimated there are
over ten billion billion
individual insects alive today.
Of all the insect groups,
it's the beetles, or coleoptera,
that have
the greatest number of species.
The biologist JBS Haldane said that
if one could conclude as
to the nature of the Creator
from a study of creation,
then it would appear that
God has an inordinate fondness
for stars and beetles.
With so much variation
in colour, form and function,
beetles have fascinated
naturalists for centuries.
Each species is wonderfully adapted
to their own unique niche.
This is the beginnings of biology
as a science that you see here,
it's this desire
to collect and classify,
which then, over time, becomes the
desire to explain and understand.
I'm going to take a picture.
Here in the suburbs of Brisbane,
every February,
there's an invasion of beetles.
The rules governing their lives
play out very differently to ours.
This is the Rhinoceros Beetle,
named for obvious reasons.
But actually, it's only the males
that have the distinctive horns
on their heads.
These beetles spend much of their
lives underground as larvae,
but then emerge en masse
as adults to find a mate and breed.
Much of this time, the males
spend fighting over females.
See that distinctive posture
that he's adopting there?
That's because I think
he's seeing his reflection in
the camera lens, and so he rears up.
Look at that! He's trying to scare
himself off.
Ha-ha-ha!
INSECT BRISTLES
You also heard that hissing sound.
That's him contract in his abdomen
which again is a defensive
posture that he adopts to scare
other males.
INSECT HISSES
Gramme for gramme, these insects are
among the strongest animals alive.
I can demonstrate that I just
getting hold of the top of his head.
It doesn't hurt him at all,
but watch what he is able to do.
Look at that.
So he is hanging on to this branch,
which is many times his own
bodyweight.
Absolutely no distress at all.
As things get smaller, it is
a rule of nature that they
inevitably get stronger.
The reason is quite simple.
Small things have relatively large
muscles compared
to their tiny body mass
and this makes them very powerful.
The beetles also appear to have a
cavalier attitude to
the effects of gravity.
They fight almost like
sumo wrestlers,
their aim is to throw each
other off the branch.
If they should fall...
they just bounce and walk off.
If I fail a similar distance
relative to my size, I'd break.
So why does size make
such a difference?
Time for a bit
of fundamental physics.
All things fall at the same rate
under gravity.
That's because they they're
following geodesics
through curved space-time,
but that's not important.
The important thing for biology is
that although everything falls at
the same rate, it doesn't meet the
same fate when it hits the ground.
A grape bounces.
A melon...
Doesn't bounce.
The reasons for that are quite
complex actually.
First of all, the grape has a larger
surface area in relation
to its volume and therefore its
mass than the melon.
Although, in a vacuum,
if you took away the air,
they would both fall at the same
rate. Actually, in reality,
the grape falls slower
than the melon.
Also, the melon is more massive
so it has more kinetic energy
when it hits the ground.
Remember physics class.
Kinetic energy is
½ MV squared,
so you reduce M,
you reduce the energy.
The upshot of that is that the melon
has a lot more energy
when it hits the ground.
It has to dissipate it in some way
and it dissipates it by exploding.
The influence of Earth's gravity
in your life becomes progressively
diminished the smaller you get.
For life at the small scale,
a second fundamental
force of nature starts to dominate.
And it's this that explains
many of those apparent superpowers.
For me, the force of gravity is
a thing that defines my existence.
It's the force that
I really feel the effects of.
But there are other forces at work.
For example if I lick my finger
and wet it, I can pick up a piece
of paper and can hold up against the
downward pull of gravity.
That's because the force
of electromagnetism is important.
In fact, it is the cohesive forces
between water molecules
and the molecules that
make up my finger
and the molecules that make
up the paper,
that are dominating this
particular situation.
That's why this piece
of paper doesn't fall to the floor.
Many insects can use
a similar effect.
Take a common fly for example.
Their feet have especially
enlarged pads onto which
they secrete a sticky fluid.
And that allows them
to adhere to rather slippery
surfaces like the glass of this
jam jar.
It allows them to do things that for
me would be absolutely impossible.
It's all down to the relative
influence of the different
forces of nature on the animal.
So the capacity to walk up walls
and fall from a great height without
breaking, plus supers trength,
are not super powers at all.
They're just abilities gained
naturally by animals
that are small and lightweight.
But this is just the beginning of my
journey into the world of the small.
Down at the very small scale,
it becomes possible to live
within the lives of other
individuals, worlds within worlds.
But just how small can animals get?
This macadamia nut plantation,
an hour outside of Brisbane,
is home to one of the very smallest
members of the animal kingdom.
These are a species
of micro-hymenoptera
known as Trichogramma.
They're basically very small wasps
and when I say small,
I mean small.
Can you see that?
They're like specks of dust.
They're less than half
a millimetre long,
but each one of those is a wasp.
It's got compound eyes,
six legs and wings.
They've even got a little
stripe on their abdomen.
And they're very precisely adapted
to a specific evolutionary niche.
The Trichogramma wasps may be
small, but they're very useful.
Theyr're natural parasites of an
insect pest species
called the nut borer moth which
attacks the macadamia nuts.
The micro-wasps lay their eggs
inside the eggs of the moths,
killing the developing moth larvae.
What you're seeing here is
the surface of the macadamia nut
and here's a small cluster of moth
eggs and there,
you see the wasp is walking
over the eggs.
They're almost
pacing out the size to see
whether the eggs are suitable
for their eggs to be laid inside.
And if we're lucky, there you go,
you see that...
That...
There we go.
The wasps emerge just nine days
later as full-grown adults.
At this scale,
they live a very sticky world,
dominated by strong
intermolecular forces.
To them, even the air is a thick
fluid through which
they essentially swim,
using paddle-like wings.
Incredibly, these tiny animals can
move about across several trees,
seeking out the moth eggs.
But what I find more remarkable
is that they do all this operating
with very restricted brain power.
One of the limiting factors that
determines the minimum
size of insects is the volume
of their central nervous system.
In other words, the processing power
you can fit inside their bodies
and these little wasps are pretty
much at their limit.
They've less than 10,000 neurons
in their whole nervous system.
To put it into perspective,
most tiny insects have 100 times
that many, but that's still
enough to allow them
to exhibit quite complex behaviour.
These micro-wasps exist at almost
the minimum possible size
for multicellular animals.
But the scale of life on our planet
gets much, much smaller.
The wasps are giants
compared to life at the very limit
of size on earth.
The smallest organisms on our
planet are also our oldest
and most abundant type of lifeforms.
These weird, rocky blobs
in the shallows of Lake Clifton,
just south of Perth,
are made by bacteria.
These mounds are called
thrombolites,
on account of their clotted
structure,
and they're built up over centuries
by colonies of microscopic
bacterial cells.
Although these colonies are rare,
by most definitions,
bacteria are THE dominant
form of life on our planet.
On every surface across every
landscape, you find bacteria.
In fact, numerically speaking,
then there are more bacteria
living on and inside my body
than there are human cells.
Bacteria come in many shapes
and forms
and are not actually
animals or plants,
instead sitting in their own
unique taxonomic kingdom.
Compared to the cells
we're made of,
bacteria are structurally much
simpler and far, far smaller.
Bacteria are typically
around two microns in size.
That's two millionths of a metre,
which is very hard to picture
but it means that you could fit
around half a million of them
on the head of a pin or,
to look at it another way,
if I took a single bacterium
and scaled it up to
the size of this coin,
then I would be 25 kilometres high.
SPLASH
Bacterial-type organisms were
the first life on Earth
and they've dominated our planet
ever since.
Excluding viruses, which by most
definitions are not alive,
bacteria are the smallest
free-living lifeforms we know of.
But what ultimately puts the limit
on the smallest size of life?
Single-cell life needs to be big
enough to accommodate all
the molecular machinery of life
and that size ultimately depends
on the basic laws of physics.
It depends on the size
of molecules which
depends on the size of atoms
which depends on fundamental
properties of the universe
like the strength of the force
of electromagnetism
and the mass of an electron.
And when you do those calculations,
you find out that the minimum size
of a free-living organism
should be around 200 nanometres
which is around 200 billionths
of a metre.
And that should be universal,
it shouldn't only apply
to life on Earth
but it should apply to any
carbon-based life
anywhere in the universe
because it depends on fundamental
properties of the universe.
From the smallest bacterium
to the largest tree,
it's your size that determines
how the laws of physics
govern your life.
Gravity imposes itself on the large,
and the electromagnetic force
rules the world of the small.
But the consequences of scale
for life on Earth
extend beyond dictating the
relationship
you have with the world around you.
Your size also influences how energy
itself flows through your body.
BATS SQUEAK FAINTLY
These are southern bent-wing bats...
..one of the rarest
bat species in Australia.
Every evening, they
emerge in their thousands
from this cave, in order to feed.
When fully grown, these
bats are just 5.5cm long,
and weigh around 18 grams.
Because of their size, they face
a constant struggle to stay alive.
BATS SQUEAK, CRICKETS CHIRP
We're using a thermal camera
here to look at the bats,
and you can see that they
appear as streaks across the sky.
They appear as brightly as me -
that's because they're
roughly the same temperature as me.
They're known as endotherms -
animals that maintain
their body temperature.
And that takes a lot of effort.
These bats have
to eat something like
three-quarters of their
own body weight every night,
and a lot of that energy goes
into maintaining their temperature.
As with all living things,
the bats eat to provide energy
to power their metabolism.
Although, like us,
they have a high body
temperature when they're active,
keeping warm is a considerable
challenge, on account of their size.
The bats lose heat mostly through
the surface of their bodies.
But because of simple laws
governing the relationship
between the surface area
of a body and its volume,
being small creates a problem.
BATS SQUEAK
So, let's look at our blocks again,
but this time for
surface area to volume.
Here's a big thing -
it's made of eight blocks
so its volume is eight units,
and its surface area is two by
two on each side, so that's four,
multiplied by the six faces is 24.
so, the surface area to
volume ratio is 24 to eight,
which is 3:1.
Now, look at a smaller thing.
This is one block,
so its volume is one unit.
Its surface area is one by one
by one, six times, so it's six.
So, this has a surface
area to volume ratio of 6:1.
So, as you go from big to small,
your surface area
to volume ratio increases.
Small animals, like bats,
have a huge surface area
compared to their volume.
As a result, they naturally
lose heat at a very high rate.
To help offset the cost of losing
so much energy in the form of heat,
the bats are forced to
maintain a high rate of metabolism.
They breathe rapidly,
their little heart races,
and they have to eat a huge amount.
So, a bat's size clearly affects
the speed at which
it lives its life.
Right across the natural world,
the size you are has a profound
effect on your metabolic rate -
or your "speed of life".
EXTREMELY FAST HEARTBEAT
For Australia's
small marsupial mouse,
even at rest,
his heart is racing away.
SLOWER HEARTBEAT
For the fox-sized Tasmanian devil,
he ticks along
at a much slower rate.
And then there's me, living life
at a languid 60 beats a minute.
Looking beyond heart rate,
your size influences the amount
of energy you need to consume,
and the rate at which
you need to consume it.
Bigger bodies have
more cells to feed.
So, you might expect that the
total amount of energy needed
goes up at the same rate
as any increase in size.
But that's not what happens.
If you plot the amount of energy
an animal uses against its mass,
for a huge range of sizes,
from animals as small as flies,
and even smaller,
all the way up to whales,
then you DO get
a straight line, but the slope
is less than one. So, that implies
that gramme for gramme,
large animals use less
energy than small animals.
This relationship between
metabolism and size
significantly affects
the amount of food
larger animals have
to consume to stay alive.
Now, if my metabolic rate scaled
one-to-one with that of a mouse,
then I would need to eat about
four kilograms of food a day.
In my language, that's around
67,000 kilojoules of energy,
which more colloquially
is 16,000 calories.
That is eight times
the amount that I take in
on average on a daily basis.
Each of the cells in my
body requires less energy
than the equivalent cells
in a smaller-sized mammal.
The reason why this should be
so is not fully understood.
It's also not clear
whether this rule of nature
gives an advantage to big things,
or is actually a constraint
placed on larger animals.
Take the relationship between
an animal's surface area
and its volume.
Big animals have a much smaller
surface area to volume ratio
than small animals, and that means
that their rate of heat loss
is much smaller.
And that means that there's an
opportunity there for large animals.
They don't have to eat
as much food to stay warm,
and therefore they can afford
a lower metabolic rate.
Now this helps explain
the lives of large,
warm-blooded endotherms,
like birds and mammals,
but doesn't hold so well
for large ectotherms,
life's cold-blooded giants.
Now, there's another theory
that says that it wasn't really
an evolutionary opportunity
that large animals took
to lower their metabolic rate.
It was forced on them.
It was a constraint, if you like.
The capillaries,
the supply network to cells,
branches in such a way that
it gets more and more difficult
to get oxygen and nutrients
to cells in a big animal
than in a small animal.
Therefore, those cells must
run at a lower rate.
They must have
a lower metabolic rate.
Or it could just be
that as you get bigger,
then more of your mass is taken up
by the stuff that supports you,
and support structures,
like bones, are relatively inert.
They don't use much energy.
But whatever the reason,
it's certainly true to say
that the only way that large animals
can exist on planet Earth
is to operate at
a reduced metabolic rate.
If this wasn't the case,
the maximum size of a warm-blooded
endotherm like me or you
would be around that of a goat.
And cold-blooded animals,
or ectotherms like dinosaurs,
could only get as big as a pony.
Any bigger, and giants
would simply overheat.
Now, there's one last consequence
of all these scaling laws
that I suspect you'll care about
more than anything else,
and it's this -
there's a strong correlation
between the effective cellular
metabolic rate of an animal
and its lifespan. In other words,
as things get bigger,
they tend to live longer.
To explore this connection
between size and longevity,
I've left the mainland behind.
For my final destination,
I've come to one of Australia's
remotest outposts.
Named Christmas Island when it was
spotted on Christmas Day in 1643,
this isolated lump of rock in
the Indian Ocean is a land of crabs.
And in their midst lurks a giant
wonder of the natural world.
This is a Christmas Island
robber crab,
the largest land crab
anywhere on the planet.
These things can grow to around
50 centimetres in length,
they can weigh over four kilograms,
and they are supremely adapted
as an adult to life on land.
They can even climb trees.
Over the years,
the crabs have become
well adapted to human co-habitation.
These things are called robber crabs
because they have a reputation for
curiosity and for stealing things,
anything that isn't bolted down.
They'll steal food and cameras
if they can get half a chance.
These giants live on
a diet of seeds and fruit,
and occasionally other small crabs.
Their large, powerful claws mean
they can also rip open
fallen coconuts.
They're really quite a menacing
animal, actually, for a crab!
What's wonderful about these crabs
is that they live through
a range of scales.
At different times of their lives,
they have a completely
different relationship
with the world around them,
simply down to their size.
Throughout their lives, robber crabs
take on many different forms.
They begin their lives
as small larvae,
swept around by the ocean currents,
and as they grow,
some of them get swept up onto
the beaches of Christmas Island,
where they find a shell, because
they are, in fact, hermit crabs.
They live inside
their shell for a while,
they continue to grow,
and eventually, as adults,
they roam the forests
like this chap here.
So these crabs, over that lifespan,
inhabit many different worlds.
On land, the adults continue to grow
and now have to support
their weight against gravity.
Compared to the smaller crabs
whizzing around,
these giants move about
much more slowly,
but they also live far longer.
Of all the species of land crab
here on Christmas Island,
robber crabs are not only
the biggest,
they're also the longest-living.
So this chap here is probably
about as old as me,
and he might live
to 60, 70, even 80 years old.
Because of the robber crab's
overall body size,
its individual cells use less energy
and they run at a slower rate
than the cells of their much
smaller, shorter-lived cousins.
The pace of life is slower
for robber crabs,
and it's this
that's thought to allow them
to live to a ripe old age.
Your size influences
every aspect of your life...
..from the way you were built...
..to the way you move...
..and even how long you live.
Your size dictates how you interact
with the universal laws of nature.
So there's a minimum size,
which is set ultimately by
the size of atoms and molecules,
the fundamental building
blocks of the universe.
And there's a maximum size
which, certainly on land,
is set by the size and
the mass of our planet,
because it's gravity that restricts
the emergence of giants.
But within those constraints,
evolution has conspired to produce
a huge range in size
of animals and plants,
each beautifully adapted to exploit
the niches available to them.
Your size influences
your form and constriction.
It determines how you
experience the world,
and ultimately,
how long you have to enjoy it.
Subtitles by Red Bee Media Ltd