-
So I'm pretty sure that I'm not
the only one in this room
-
who at some point have found myself,
you know, looking up towards the stars,
-
and wondered, you know, "Are we it,
-
or are there other living planets
out there such as our own?"
-
I guess it is possible
that I'm then the only person
-
who has obsessed enough
about that question
-
to make it my career.
-
But moving on.
-
How do we get to this question?
-
Well, I would argue the first thing to do
-
is to turn our eyes back down from the sky
to our own planet, the Earth.
-
And think about just how lucky
did the Earth have to be
-
to be the living planet it is.
-
Well, it had to be
at least somewhat lucky.
-
Had we been sitting closer to the Sun
-
or a bit further away,
-
any water that we have had
would have boiled off or frozen over.
-
And I mean, it's not a given
that a planet has water on it.
-
So had we been a dry planet,
-
there would not have been
a lot of life on it.
-
And even if we had had all the water
that we have today,
-
if that water had not been accompanied
-
by the right kind of chemicals
to get life going,
-
we would have a wet planet,
but just as dead.
-
So with so many things that can go wrong,
-
what are the chances that they go right?
-
What are the chances that the planet forms
-
with at least the basic ingredients needed
-
to have an [unclear] of life happening?
-
Well, let's explore that together.
-
So if you're going to have
a living planet,
-
the first thing you're going to need
-
is a planet.
-
(Laughter)
-
But not any planet will do.
-
You're probably going to need
a rather specific and earthlike planet.
-
A planet that is rocky,
-
so you can have both oceans and land,
-
and it's sitting neither too close
nor too far away from its star,
-
but at the just-right temperature.
-
And it's just right
for liquid water, that is.
-
So how many of these planets
do we have in our galaxy?
-
Well, one of the great discoveries
of the past decades
-
is that planets are incredibly common.
-
Almost every star
has a planet around them.
-
Some have many.
-
And among these planets,
-
on the order of a few percent
are earthlike enough
-
that we would consider them
potentially living planets.
-
So having the right kind of planet
is actually not that difficult
-
when we consider that there's
about 100 billion stars in our galaxy.
-
So that gives you about a billion
potential living planets.
-
But it's not enough to just be
at the right temperature
-
or have the right overall composition.
-
You also need the right chemicals.
-
And what the second and important
ingredient to make a living planet is --
-
I think it's pretty intuitive --
-
it's water.
-
After all, we did define our planet
as being potentially living
-
if it had the right temperature
to keep water liquid.
-
And I mean, here on Earth,
life is water-based.
-
But more generally,
-
water is just really good
as a meeting place for chemicals.
-
It is a very special liquid.
-
So this is our second basic ingredient.
-
Now the third ingredient, I think,
-
is probably a little bit more surprising.
-
I mean, we are going to need
some organics in there,
-
since we are thinking about organic life.
-
But the organic molecule
-
that seems to be at the center
of the chemical networks
-
that can produce biomolecules
is hydrogen cyanide.
-
So for those of you who know
what this molecule is like,
-
you know it's something
that it's a good idea to stay away form.
-
But it turns out
-
that what's really, really bad
for advanced life forms
-
such as yourselves,
-
is really, really good
to get the chemistry started,
-
the right kind of chemistry
that can lead to origins of life.
-
So now we have our three
ingredients that we need,
-
you know, the temperate planet,
-
water and hydrogen cyanide.
-
So how often do these three come together?
-
How many temperate planets
are there out there
-
that have water and hydrogen cyanide?
-
Well, in an ideal world,
-
we would now turn one of our telescopes
towards one of these temperate planets
-
and check for ourselves.
-
Just, "Do these planets have water
and cyanides on them?"
-
Unfortunately, we don't yet
have large enough telescopes to do this.
-
We can detect molecules
in the atmospheres of some planets.
-
But these are large planets
-
sitting often pretty close to their star,
-
nothing like these, you know,
just-right planets
-
that we're talking about here,
-
which are much smaller and further away.
-
So we have to come up with another way.
-
And the other way that we have
conceived of and then followed
-
is to instead of looking
for these molecules
-
in the planets when they exist,
-
is to look for them in the material
that's forming new planets.
-
So planets form in discs
of dust and gas around young stars.
-
And these discs get their material
from the interstellar medium.
-
Turns out that the empty space
you see between stars
-
when you are looking up towards them,
asking existential questions,
-
is not as empty as it seems,
-
but actually full of gas and dust,
-
which can, you know,
come together in clouds,
-
then collapse to form these discs,
stars and planets.
-
And one of the things we always see
when we do look at these clouds
-
is water.
-
You know, I think we have a tendency
to think about water
-
as something that's,
you know, special to us.
-
Water is one of the most abundant
molecules in the universe,
-
including in these clouds,
-
these star- and planet-forming clouds.
-
And not only that --
-
water is also a pretty robust molecule:
-
it's actually not that easy to destroy.
-
So a lot of this water
that is in interstellar medium
-
will survive the [unclear] dangers,
collapse, journey from clouds
-
to disc, to planets.
-
So water is alright.
-
That second ingredient
is not going to be a problem.
-
Most planets are going to form
with some access to water.
-
So what about hydrogen cyanide?
-
Well, we also see cyanides
and other similar organic molecules
-
in these interstellar clouds.
-
But here, we're less certain
about the molecules surviving,
-
going from the cloud to the disc.
-
They're just a bit more delicate,
a bit more fragile.
-
So if we're going to know
that this hydrogen cyanide
-
is sitting in the vicinity
of new planets forming,
-
we'd really need to see it
in the disc itself,
-
in these planet-forming discs.
-
So about a decade ago,
-
I started a program
to look for this hydrogen cyanide
-
and other molecules
in these planet-forming discs.
-
And this is what we found.
-
So good news, in these six images,
-
those bright pixels represent emissions
originating from hydrogen cyanide
-
in planet-forming discs
hundreds of light-years away
-
that have made it to our telescope,
-
onto the detector,
-
allowing us to see it like this.
-
So the very good news
-
is that these discs do indeed have
hydrogen cyanide in them.
-
That last, more elusive ingredient.
-
Now the bad news is that we don't know
where in the disc it is.
-
If we look at these,
-
I mean, no one can say
they are beautiful images,
-
even at the time when we got them.
-
You see the pixel size is pretty big
-
and it's actually bigger
than these discs themselves.
-
So each pixel here
-
represents something that's much bigger
than our solar system.
-
And that means
-
that we don't know where in the disc
the hydrogen cyanide is coming from.
-
And that's a problem,
-
because these temperate planets,
-
they can't access
hydrogen cyanide just anywhere,
-
but it must be fairly close
to where they assemble
-
for them to have access to it.
-
So to bring this home,
let's think about an analogous example,
-
that is, of cypress growing
in the United States.
-
So let's say, hypothetically,
-
that you've returned from Europe
-
where you have seen
beautiful Italian cypresses,
-
and you want to understand, you know,
-
does it make sense to import them
to the United States.
-
Could you grow them here?
-
So you talk to the cypress experts,
-
they tell you that there is indeed
-
a band of not-too-hot, not-too-cold
across the United States
-
where you could grow them.
-
And if you have a nice,
high-resolution map or image like this,
-
it's quite easy to see
that this cypress strip
-
overlaps with a lot of green
fertile land pixels.
-
Even if I start degrading
this map quite a bit,
-
making it lower and lower resolution,
-
it's still possible to tell
-
that there's going to be some fertile land
overlapping with this strip.
-
But what about if the whole United States
-
is incorporated into a single pixel?
-
If the resolution is that low.
-
What do you do now,
-
how do you now tell whether you can grow
cypresses in the United States?
-
Well the answer is you can't.
-
I mean, there's definitely
some fertile land there,
-
or you wouldn't have
that green tint to the pixel,
-
but there's just no way of telling
-
whether any of that green
is in the right place.
-
And that is exactly the problem
we were facing
-
with our single-pixel
images of these discs
-
[unclear] hydrogen cyanide.
-
So what we need is something analogous
-
to those low-resolution maps
that I just showed you
-
to be able to tell whether there's overlap
between where the hydrogen cyanide is
-
and where these planets
can access it as they are forming.
-
So coming to the rescue, a few years ago,
-
is this new, amazing,
beautiful telescope ALMA,
-
the Atacama Large Millimeter
and submillimeter Array
-
in northern Chile.
-
So, ALMA is amazing
in many different ways,
-
but the one that I'm going to focus on
-
is that, as you can see,
I call this one telescope,
-
but you can there are actually
many dishes in this image.
-
And this is a telescope
that consists of 66 individual dishes
-
that all work in unison.
-
And that means that you have a telescope
-
that is the size of the largest distance
that you can put these dishes
-
away from one another.
-
Which in ALMA's case are a few miles.
-
So you have a more
than mile-sized telescope.
-
And when you have such a big telescope,
-
you can zoom in on really small things,
-
including making maps of hydrogen cyanide
in these planet-forming discs.
-
So when ALMA came online a few years ago,
-
that was one of the first things
that I proposed that we use it for.
-
And what does a map of hydrogen cyanide
look like in a disc?
-
Is the hydrogen cyanide
at the right place?
-
And the answer is that it is.
-
So this is the map.
-
You see the hydrogen cyanide emission
being spread out across the disc.
-
First of all, it's almost everywhere,
-
which is very good news.
-
But you have a lot
of extra bright emission
-
coming from close to the star
towards the center of the disc.
-
And this is exactly
where we want to see it.
-
This is close to where
these planets are forming.
-
And this is not what we see
just towards one disc --
-
here are three more examples.
-
You can see they all show
the same thing --
-
lots of bright hydrogen cyanide emission
-
coming from close
to the center of the star.
-
For full disclosure,
we don't always see this.
-
There are discs where we see the opposite,
-
where there's actually a hole
in their emission towards the center.
-
So this is the opposite
of what we want to see, right?
-
This is not places where we could research
-
if there is any hydrogen cyanide around
where these planets are forming.
-
But in most cases,
-
we just don't detect hydrogen cyanide,
-
but we detect it in the right place.
-
So what does all this mean?
-
Well, I told you in the beginning
-
that we have lots
of these temperate planets,
-
maybe a billion or so of them,
-
that could have life develop on them
-
if they have the right ingredients.
-
And I've also shown
-
that we think a lot of the time,
the right ingredients are there --
-
we have water, we have hydrogen cyanide,
-
there will be other
organic molecules as well
-
coming with the cyanides.
-
This means that planets
with the most basic ingredients for life
-
are likely to be incredibly
common in our galaxy.
-
And if all it takes for life to develop
-
is to have these basic
ingredients available,
-
there should be a lot
of living planets out there.
-
But that is of course a big if.
-
And I would say the challenge
of the next decades,
-
for both astronomy and chemistry,
-
is to figure out just how often
-
we go from having
a potentially living planet
-
to having an actually living one.
-
Thank you.
-
(Applause)
closed TED
