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The galactic recipe for a living planet

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

Did you know that one of the most notorious poisons is also a key ingredient for life as we know it? Join space chemist Karin Öberg and learn how she scans the universe in search of this paradoxical chemical using ALMA, the world's largest radio telescope, to detect hotbeds of molecular activity and the formation of life-sustaining planets.
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Video Language:
English
Team:
closed TED
Project:
TEDTalks
Duration:
13:32

English subtitles

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