Science
How Webb Illuminates Stars’ Cloudy Origins
In this episode of NASA's Curious Universe, host Jacob Pinter explores the fascinating process of star formation from dark clouds of gas and dust. Featuring insights from astronomer Evina Vandysv...
How Webb Illuminates Stars’ Cloudy Origins
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You're listening to NASA's Curious Universe.
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I'm your host, Jacob Pinter.
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Out in the cosmos, in the space between stars, gas, dust, and ice, mingle in dark clouds.
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Eventually, after millions of years, these clouds will evolve into stars with planets
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orbiting them.
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With telescopes, we can see how it all happens.
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And in a lab in the Netherlands, you can almost put your hands on it.
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I would like to say that this is one cubic-centred video of an interstellar space or something
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like that that we have in the lab.
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Evina Vandysvick is an astronomer based at the University of Lighten in the Netherlands.
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To figure out how those dark clouds become stars, she combines telescope data with what
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she sees in the laboratory.
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Your experiments in the lab on Earth will take hours, which is good because then students
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can finish it in a day.
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Whereas in space, they will take hundreds of thousands of years.
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On Earth, you can't manage a perfect simulation of space.
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But in some ways, you can get close.
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Those clouds of dust and gas are far colder than anything that happens naturally on Earth.
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They can be below minus 400 degrees Fahrenheit, not far from absolute zero.
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Reaching those temperatures is actually not the hard part.
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We can't achieve the emptiness of space.
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And even the best ultra-high vacuum that we can make in a laboratory on Earth is still
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a million times more dense than what we have in space.
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So when an astronomer talks about a dense dark cloud, it's still much more empty than anything
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we have in a laboratory here on Earth.
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In the lab, you get a close-up view of the same chemicals we find out in space.
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And that helps us understand how they behave and how we can detect them.
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Scientists study these clouds and their chemistry in a number of ways.
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And they have a groundbreaking new tool.
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NASA's James Webb Space Telescope.
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In space, a million miles from Earth, Webb is giving us views of the cosmos that no other telescope can.
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And that includes the clouds where stars form.
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Now, Evina is a distinguished astronomer who is one a number of major awards.
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But at the beginning of her career, she didn't set out to study space.
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As a high school student, Evina decided she wanted to be a chemist.
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At university, she realized she was interested in physics, too.
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And then there was one other influence.
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And then my boyfriend's husband was actually studying astronomy.
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And he realized that there were also molecules in space, that there was chemistry in space.
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And so at some stage, he actually said to me,
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well, isn't that something for you?
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And so that is how I actually made the transition from pure chemistry,
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studying theoretical chemistry to astronomy.
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I mean, that's a good boyfriend who points you in the right direction, I guess.
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Well, I've never regretted that transition because the space between the stars is such a fantastic
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chemical laboratory, also, that it's much more exciting than a laboratory here on Earth.
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Scientists are studying those chemicals to understand not only how planets form,
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but how they end up with water and even the building blocks of life.
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And by exploring this process in space, we can also learn more about why Earth has water and life.
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For decades, Evina has been part of an international collaboration
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to make that research possible.
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NASA and Issa, the European Space Agency, built an instrument on the James Webb Space Telescope,
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called MIRI.
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MIRI is an acronym that stands for Mid-Inferred Instrument.
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One of the things that's so special about web is that it sees an infrared,
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a part of the light spectrum human eyes can't see.
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If you've ever seen a movie character use night vision goggles that detect heat signatures,
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even in the dark, well, Webb is doing something similar to that.
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Looking at infrared light allows scientists to peer inside dark clouds and see details that
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otherwise stay hidden. Of the four instruments on board Webb, three of them focus on a portion
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called the near infrared. MIRI gives a different view, like a painter unlocking a new set of colors.
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It collects images and also spectra, scientific data that provide detailed information about molecules in space.
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But MIRI also presents a unique challenge.
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Webb has to stay cold, otherwise heat from the sun and Earth would interfere with its night vision
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goggle view. So Webb has a huge sun shield that blocks the sun's radiation, keeping the telescope
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extra cold. MIRI needs to stay even colder than the rest of the telescope.
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So on board Webb, MIRI has its own special refrigerator called the cryocooler,
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which uses helium to maintain a temperature below minus 440 degrees Fahrenheit,
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hovering just a few degrees above absolute zero.
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And Webb doesn't do this research alone. Scientists like Evina can use Webb to tag team with other
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telescopes, including a powerful one in Chile called Alma, the Atacama Large Millimeter Rere.
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I was excited to ask Evina about Webb and how she helped bring part of the telescope to life.
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When did you first start working on the James Webb Space Telescope? I wonder if you can take
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me back right to the beginning. Right, so that must have been sort of the late 1990s. We were just
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coming out of the infrared space observatory, the ISO satellite. That was an ESA satellite that for the
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first time had measured infrared spectra above the Earth's atmosphere. And we had realized how
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incredibly rich the spectra were. And at that time, the mid infrared instruments were still sort
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of TBD. It was still not sure that it was going to be on Webb. And so it was that late 1990s,
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early 2000s, when as a small group, we started to make the case and said, you know, Webb really has
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to have also a mid infrared instruments. Unfortunately, we're successful in making that case. And it
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became not just a simple imager, but also with a proper spectrometer on it that we argued very
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hard for based on the data that we had gotten from that earlier satellite. And that's what we now have.
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And so the first public data came six or seven months, I think, after the telescope launched.
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Those were some agonizing months still where, you know, the telescope had unfolded. It was getting
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sharp, but Miri still had to be cold. And so that was always one of those moments, you know, will the
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refrigerator turn on? Will the cooler turn on to make the instrument cold? So that was for me,
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an enormous relief when we could see on the the live webcam, the temperature actually of Miri going
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down and down and down until finally it was at the temperature where it could actually operate.
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What a whirlwind. Yeah, yeah, yeah, yeah. And once you did get that data for the first time,
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and then you got more data and you got the chance to work through it, what did you actually see at first?
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And I guess can you compare the details you saw from James Webb to data that you had had before James
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Webb launched? Yeah, that's a very good question. Of course, in the beginning, you tried to also look
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at something that you've seen before. One of that was images. So one thing that's
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J.D. Ristie, of course, excels at is the imaging and the really fantastic and beautiful
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in-depth imaging that is not possible with Webb so much detail that you see there. But
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my scientific heart is mostly in the spectra. And when we first got some of those spectra,
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you know, it was just a much richer, a much higher quality than we had been anticipating. And so I
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remember seeing some of it and saying, wow, if I compare that with in particular either the
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infrared space observatory from the 1990s or the speed space telescope, which also has been a
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fantastic trailblazer for Webb, then we could see just the enormous improvement of
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in quality of the spectra. What used to be just tiny little wiggles in the older data now over
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sort of booming lines that we could very clearly see and identify. So that was just a one of these
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moments that you dream of. So let's talk a little bit more about what we know about the science and
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what we're learning. I'm imagining a planetary system kind of like a cake. Like by the time you get
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to our solar system and you have all these beautiful planets, it's, you know, it's done and the
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frosting's on it and it's ready to eat. But if you're going to make a cake, you need a recipe.
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And before you start the recipe, you have to gather your ingredients. So I'm wondering if we
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are going to make a star or a planetary system, what are the ingredients that we need or that we
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might see at the beginning that will turn into that system? Right. So indeed, that's an analogy that
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I very much like that there's a lot of excellent research being done on exoplanets, but they have
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already come out of the oven and we are actually providing the ingredients that go into making that
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cake. So actually does ingredients start already at a very early stage when the dark cloud in which
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a star forms is actually collapsing under its own weight. And those clouds are cold and that means
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that atoms and molecules that are in the gas can actually freeze out and collide with the cold
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dust grains and form an icy layer. Think a little bit about it when you have your car on a
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cold winter day and you know that an icy layer can form on it simply from the atmosphere molecules
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freezing out onto your windshield. So the same thing happens there with these dust grains and
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atoms molecules freeze out, but then also new reactions can actually occur on those tiny little
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dust grains. They are sort of a place where atoms and molecules meet and greet and can actually
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form new compounds like water for example most of the water that we see and that we have here
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on planetary systems was actually formed on those tiny little dust grains in the cloud out of
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the star and its planetary system collapsed. Okay so that is something that wep can now study with
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exquisite detail. It sees not just the water ice and the carbon dioxide ice, but it sees also
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molecules much more complex molecules. For example, ethanol, even ethanol, simple alcohols,
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simple sugars, molecules that you know could be important in not just bringing water but also
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bringing organic material to the services of new planets. So a lot of the chemistry is so a lot of
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those ingredients actually that you need to make your cake are already inherited from that very
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early stage. And so if those are our ingredients, what does the recipe look like then? Like how does
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all of that come together and get smushed into something and come out the other side as a star
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and maybe a planet or some planets orbiting it? Well that is a very good question. The star basically
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is originates from the collapse of the cloud and then the process of it heating up over time
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that's basically gravity doing its work. Exactly how a planetary system is formed that is still
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one of the big questions in astrophysics. And what we do know is that these tiny little
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dust grains, just a small fraction of the widths of your hair, that they can actually collide and
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grow to larger bodies and say pebbles, say rocks, say planetesimals as we call them,
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comet-sized bodies, about a kilometer in size. Those pebbles and those planetesimals, those are
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actually the building blocks of new planets. I remember way back in elementary school or something.
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You know we learned that the earth is 4.6 billion years old and that before it became a planet,
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it was this disk of spinning. I don't even know what dust and gas maybe. Is that something that
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you see out there in the cosmos as well? Oh yes indeed. It was in the 1990s that actually these
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disks were actually seen, convincingly seen for the first time. And then Alma, the Alta Gamma
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Largemony-Limiter array has now beautifully imaged these rotating disks of gas and dust around
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many young stars. So we now know that they have the size of typically our solar system
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and that they are also not smooth. They contain gaps, cavities, structures, bumps in which the
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grains actually collect, we call them dust traps. And so that all now plays a role in what we are
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now seeing with GDBST. And what we see there is just an incredible richness of molecules.
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Some of them are very rich in water, others are rich in CO2. And then the big surprise is that we
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found some disks that are actually very rich in carbon containing molecules. They have very little
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water, but they are booming in, for example, a settling and some of them even in benzene. So
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there's a lot of my sort of chemistry and cooking still going on in that inner part of the disks
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around the young stars that we do not fully understand yet. But that may have a large influence
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on what kind of planets we actually make there. I mean, one of the big, maybe the biggest
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questions that NASA and other space organizations want to know is, could there be life out there,
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could we somehow detect signs of life? And we're looking for it in all kinds of different ways. But
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when I hear you talk about the ingredients for stars in planetary systems and finding water
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in lots of places and finding some organic chemistry or precursors to organic chemistry,
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that's where my mind goes right away. Is that something you think about? Is it something you
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look for? And I guess how do you think your research fits into that?
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Yeah, it's of course the ultimate question. And the question that certainly fascinates humanity.
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I always like to get to the point of providing the biologist with the ingredients.
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Water is clearly there. There's plenty of water around most forming stars and in most disks
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around these young stars where planet formation occurs. So there is quite a lot of water.
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Not all of them may make it to the threshold planet forming region, but certainly in the disk as a whole,
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there is there is a lot of water. There's certainly a lot of organic material. And so those
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ingredients are available. What the steps are that then will ultimately produce life is something that
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I very much like to leave to my organic chemistry and biology colleagues. There's a lot of work
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going on now in trying to understand how to make the first cell, for example. We know we have all
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the basic building blocks, but how to then actually put a puzzle together, how to put a sort of
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Lego pieces together to get there. That is something that certainly I don't have enough expertise in.
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I'm probably a little bit more conservative than some of my other colleagues in terms of when we
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will find the signatures of life. That's still going to take some time and instruments and
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missions beyond JDBST. But all the steps that we are making now in terms of knowing what the
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ingredients are, where and how everything is coming together. That are just all key steps in this
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whole sort of story towards finding life elsewhere in the universe. Well, I've got one final question
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for you. The name of our show is Curious Universe. So I always like to ask, what are you still curious
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about? Well, I should say as a chemist, I'm really curious as to how those atoms come together to
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form, you know, even the simplest molecules. We have theories for that, but at some stage,
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you would really like to see it with your own eyes. I think actually just knowing what made our
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earths and whether or not it is special, I think that would also be an incredibly important question,
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putting our own earth into context. I'm still from the Star Trek generation, so sometimes I wish
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that I could just be a science officer on a starship and just travel to the Orion Nebula and really
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take a scope of the material there and just study it in great detail and then see what is
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everything that is really there.
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Avena Vandyshuk is an astronomer based at the University of Leiden in the Netherlands.
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You know, some of Webb's most striking images feature nebulae where stars are born.
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We're going to include one of those images in the web page for this episode.
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It's a section of the lobster nebula, which is several thousand light years away from earth.
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In this image, you see young stars that are extremely hot, some of them eight times hotter than
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the sun. And these infant stars have shaped jagged peaks in the nebula's cloud and carved out
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a cavity in the gas. I mean, you can really see how punishing the winds and radiation are that come
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from stars being born. You can find that web page and transcripts for every episode of this show
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at nasa.gov slash curious universe. For more information and the latest news about the James
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Web Space Telescope, head to nasa.gov slash web. And if you liked this story, you will love NASA's
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documentary Cosmic Dawn. To deliver the science data you heard about in this episode, Webb's
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engineers spent decades designing the telescope, building and testing it, and finally launching it
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a million miles into space. We had this singular purpose for 25 years to make the James Web Space
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Telescope a reality. And you know, people didn't think we were nuts at first because the technical
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challenges were so daunting. And the number of things we had to advance or literally invent were
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numerous. Pops and popcorn and experienced the incredible true story of the James Web Space Telescope
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in the NASA documentary Cosmic Dawn, head to nasa.gov slash Cosmic Dawn.
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This is NASA's curious universe. This episode was written and produced by me, Jacob Pinter.
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Our executive producer is Katie Cohnens. The curious universe team also includes Christian Elliott
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and of course, Patty Boyd. Christopher Kim designed our show art. Our theme song was composed by Matt
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Russo and Andrew Santiguita of System Sounds. We had fact checking help on this episode and
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others in our web series from Laura Betts, Elise Fisher, Amber Straun and Stephanie Mylon.
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