Planetary Radio: Space Exploration, Astronomy and Science - JWST confirms its first exoplanet
Episode Date: February 1, 2023The James Webb Space Telescope has confirmed the discovery of its first exoplanet. Jacob Lustig-Yaeger, one of the leads on the team that made the detection, joins us to discuss the details. We share ...info on the Juno mission to Jupiter's next flybys of Io, let you know how to spot the "green comet" visiting our part of the Solar System, and provide insights on the night sky in What's Up. Discover more at https://www.planetary.org/planetary-radio/2023-JWST-confirms-its-first-exoplanetSee omnystudio.com/listener for privacy information.
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The new age of planet hunting with JWST begins, this week on Planetary Radio.
I'm Sarah Al-Ahmed of the Planetary Society, with more of the human adventure across our solar system and beyond.
The James Webb Space Telescope has found its first exoplanet.
Jacob Lustig-Yager, one of the leads on the team that confirmed the new world,
joins us to discuss the groundbreaking discovery and what it means for the future of exoplanet hunting.
We'll share a short report on the Juno mission's planned flybys of Jupiter's volcanic moon Io,
and our CEO Bill Nye the Science Guy will pop in to tell you how to spot the green
comet that's visiting our part of the solar system. We'll close out our show with Dr. Bruce Betts as
he brings you up to speed on what's going on in the night sky and what's up. Now we turn to this
week's space mission briefings. In April, the European Space Agency's Jupiter Icy Moons Explorer, or JUICE mission, will
finally embark on its journey to the Jovian system.
It will study Jupiter's potentially ocean-bearing moons Ganymede, Europa, and Callisto.
The mission is all set to be shipped to its launch facility in French Guiana.
It's going to take about eight years for it to reach Jupiter,
but we know that the data will be worth the wait. The Lucy spacecraft, which NASA launched in October of 2021 on a mission to study Jupiter's Trojan asteroids, is still facing issues with one of
its two solar arrays. The mission team says that the spacecraft is still functioning well enough
to do its job, but their attempts to fix the array have been unsuccessful so far. Don't worry, though. The team's efforts to correct
the deployment will pick back up when Lucy moves back towards the Sun on its trajectory toward
Jupiter later this year. We'd also like to send a huge congratulations to the team behind NASA's
Ingenuity Mars Helicopter. The small experimental drone spacecraft has successfully completed its 40th flight on Mars.
The little copter has accompanied the Perseverance rover on its journey
across the Martian surface for almost two years now.
That's so much longer than it was expected to work, and that team should be so proud.
You can learn more about these and other stories in
our January 27th edition of The Downlink. That's the Planetary Society's weekly newsletter.
Read it online or get it sent to your inbox for free every Friday at planetary.org slash downlink.
In our most recent show, we shared some of the amazing things that NASA's Juno spacecraft has been learning about Jupiter's moons.
Our guests teased that the spacecraft has some upcoming flybys of Io, the most volcanic body that we've ever discovered in our solar system.
The data and images from those flybys are going to blow us all away.
The Planetary Society's senior editor, Jason Davis, has just published an article
on this subject, and he's here to tell us more. Hi, Jason. Thanks for joining me.
Hey, Sarah. Thanks so much for having me.
Yeah, so last week I had Scott Bolton, the principal investigator of Juno's mission to
Jupiter, here to talk about all of the amazing moon science that they've been doing over around
Jupiter. But it's perfect timing. You just came out with a new article about Juno's flybys of Io.
You want to tell us a little bit about what Juno has in store for us?
Yeah, so exciting that in Juno's extended mission, you know, it's getting a look at
some of the Galilean moons. We've already seen Ganymede in Europa, and now it's time for Io.
So cool. Throughout this year, spacecrafts can be
getting closer and closer on its long orbits of Jupiter until finally it does a really nice close
flyby on December 30th. So mark your calendars nearly a year from now. And then another one on
February 3rd of next year. That's awesome. I'm so looking forward to those images from JunoCam.
You know, anytime we get a glimpse of that moon, it is so just
beautiful and absolutely terrifying. But just getting a closer look at it for the first time
in ages is going to be amazing. Yeah, yeah. JunoCam is so neat to remember that this was
kind of an add-on instrument at the last minute before Juno launched. It wasn't actually a science
instrument, but I believe it was Scott Bolton, who you just mentioned, who said, you know, we cannot go to Jupiter without a camera. And they managed to get this
little camera on there. And it's just delivered these amazing pictures of Jupiter and now some
of these moons and can't wait to see what Io looks like through its lens.
Yeah, even from a distance, just the images of the volcanoes exploding. And when I spoke to Scott
Bolton last week, he was talking about how there's just straight up lakes of lava on that moon. So it's going to be really interesting to learn more.
I know that when they're going to be making these close passes, they're going to be using
an interesting tactic to try to use those passes to learn more about the internal workings of that
moon. Can you tell me more? One of the big questions about Io is how does it actually
work? We know that it gets squeezed on by Jupiter and Europa and Ganymede, but we don't know exactly how the heat is generated inside the moon and how that heat transforms the magma deep inside it into these lava pools that spill out onto the surface and shoot into space.
So scientists are really keen to try to figure out exactly how that works and model it.
So one way we can do that is just watching how Io's gravity affects the spacecraft.
It'll transmit a signal to Earth.
And as Io's gravity kind of unevenly tugs on it, that signal will shift a little bit.
We can actually see then or try to determine what's going on inside the moon.
Are they going to have to turn the spacecraft in order to send that signal back?
And is that going to impact what images we get of the moon when it flies by?
It will only do this, as far as I know, on those two really close flybys. And they will have to
orient the spacecraft in a very specific way to do that. And that'll put JunoCam's kind of playing
second fiddle, not in the best position for pictures. But after it does its flyby and sort
of Juno is receding into the distance, JunoCam should still be there and manage to get a really
cool kind of half-lit photo of Io on the side that faces Jupiter. So that'll be a cool, really
neat perspective on the moon that we don't see that often. Yeah, it'll be exciting to see what
happens.
That's really cool. Is there anything you're super excited about personally to learn about Io?
Yeah, I'm really hoping that we'll be able to see some kind of changes on the surface. And that's kind of the goal is they fly by the moon again and again, they can see like what's actually
happening. Are we seeing lava spilling onto the surface? Will we see a volcano erupting up into
space, which we have captured before with other missions? Just the chance that we might see this
jaw-dropping picture of a volcano doing something really cool is definitely what I'm looking forward
to the most. Same. That's going to be amazing. Well, thanks for joining me, Jason. These flybys
are going to teach us just so much about the geology and just the geophysics of this volcanic
moon. And I'm really excited to learn what it's going to teach us about so much about the geology and just the geophysics of this volcanic moon.
And I'm really excited to learn what it's going to teach us about Jupiter. So I hope everyone checks out Jason's article. I'm going to put it up on the page for this Planetary Radio episode
at planetary.org slash radio. So you can get all the information that you want about Juno's
new flybys of Io. Now, before we get into our main subject for today, we'd like to take a moment to share more
about how you can spot a beautiful green comet that's swinging close by Earth this week.
Here's the Planetary Society's CEO, Bill Nye, with the details.
Right now, a comet from the outer edges of our solar system is passing close to Earth
for the first time in 50,000 years. Here's how to see it. Comet 2022 E3, ZTF,
sometimes referred to as the Green Comet, will be closest to Earth on February 1st,
and around that time, if you are somewhere with a dark sky, it may be visible to the naked eye,
or better yet, use binoculars. It will most likely look like a faint smudge in the sky
rather than a bright object,
but with a telescope, you might see its tail
and its greenish color.
To find the comet, look in the northern sky
soon after sunset.
And remember, even though it may look like
a dim smudge in the sky,
this particular comet takes about 50,000 years
to orbit the sun,
so literally no one has
seen it since the Stone Age.
The Green Comet.
Watch for it.
Well, you heard him folks.
Grab your binoculars if you got them and let us know if you spot that comet.
You can write us at planetaryradio at planetary dot org.
Now it's time to get into our main topic for today, planet hunting.
You know, it wasn't so long ago that finding exoplanets orbiting distant stars was really difficult.
But with advances in technology, new space telescopes, and a new generation of people with a passion for finding worlds,
humanity can be proud to report that we've discovered more than 5,000 exoplanets beyond our solar system.
Now NASA's James Webb Space Telescope, or JWST,
has officially joined the planet-finding effort and has discovered its first world.
JWST is a new infrared space telescope that was decades in the making.
It's revolutionary in so many ways
and has already taught us a lot about distant
galaxies and the early universe. But part of what makes it so powerful in our quest
to learn more about the cosmos is JWST's ability to not only find exoplanets, but analyze
the atmospheres of these distant worlds and tell us more about their composition.
Our guest today is Jacob Lustig-Jager. He's an astronomer,
astrobiologist, and exoplanet hunting postdoctoral fellow at the Johns Hopkins University Applied
Physics Laboratory in Maryland, USA. He and his colleague Kevin Stevenson lead the team that
recently announced the discovery of the first confirmed exoplanet with JWST, a world named LHS 475b. It orbits a red dwarf star 41
light-years away in the constellation of Octans, and excitingly, it's almost exactly the same size
as Earth. Of course, it's a very different world from Mars, but still! Their team first observed the exoplanet on August 31, 2022,
and it's just one exoplanet in a series of Earth-sized worlds their team is planning to study.
They're using a method called transmission spectroscopy to teach us more about the
atmospheres of worlds that are similar to the size of ours. When distant exoplanets pass between us
and their stars, we can study the light that
passes through the air shrouding those worlds and learn more about their atmospheric composition.
JWST is the only telescope capable of accomplishing this feat for rocky Earth-sized
worlds, so this moment marks a whole new age of exoplanet detection and study.
Welcome to Planetary Radio, Jacob.
It's good to be here. Thanks for having me.
I want to say congratulations to you and your team for detecting the first planet with the James Webb Space Telescope.
I mean, it's a whole new age of exoplanetary discovery, and your team is going to be in the history books.
Yeah, thank you. Thank you.
The rate of exoplanet detection is really increasing these days with over 5,000 discovered.
So it's an exciting time to be studying exoplanets.
Oh, for sure.
I mean, I got really interested in astronomy as a very young child.
I think it was right after the second exoplanet was discovered.
And now there's thousands of them.
It's a good time to be in this field.
Yeah, definitely.
Now there's thousands of them.
It's a good time to be in this field.
Yeah, definitely.
I watched your press conference at the 241st American Astronomical Society meeting in January, and that had to be so exciting to finally get up there and share this discovery with
the astronomical community.
I mean, after so many years of dedicating your life to exoplanet discovery, like, what
did that feel like?
It was really cool.
Like, what did that feel like?
It was really cool.
JWST has been in science operation mode since July, taking data diligently.
And we've had these data on our hands since early September and worked really hard to put this out and sort of get the materials ready for the AAS conference.
So it was really nice to be able to share that both with the press and with the astronomical
astrophysical community.
Did you have to keep any of it secret for a little while there as you're like generating graphics? A little bit, but early versions of our work was shown to some of our colleagues at a
meeting at Space Telescope Science Institute in Baltimore in early December. So it was sort of
trickling out there, But certainly we did the coordinated
press releases and that caught a lot of attention. And just to give a little bit of like your
backstory in this, you know, you've been studying exoplanets since your undergraduate time at UC
Santa Cruz. And then you just kept on going when you went to get your PhD at the University of
Washington. Now you're hanging out at the Johns Hopkins Applied Physics Lab doing your postdoc work.
And I have to ask, what started this journey?
Why are you so in love with exoplanets?
And why particularly Earth-like exoplanets?
At UC Santa Cruz, I went in there undeclared, not really sure what I wanted to major in.
I like math.
I knew I wanted to go into some area of science.
I was thinking about
cognitive science and chemistry and physics, definitely. And then I sort of decided on a
physics bachelor's path. And at a certain point, I think in a junior year, needed some upper
division electives to satisfy credits. And a friend of mine said, Hey, this exoplanet class taught by
Jonathan Fortney looks great. You should take this with me since you like astrophysics. And I was
like, I like astrophysics. Yeah, I guess you're right. You're right. You know, sometimes your
friends know you better than you know yourself at times. And you know, that class was an introduction
for me to exoplanets. Jonathan talked about this app called Exoplanets, I think. I still have it on
my phone where you can follow new discoveries. And I just sort of fell in love, thought, wow,
this field is up and coming. There's sort of guaranteed to be amazing discoveries over the
next, you know, any number of years, five years, 10 years, this field will continue to grow. So
kind of set me on a path to doing research
with that professor, Jonathan Fortney. And then he helped me apply to grad school where I got into
the University of Washington in Seattle and moved up there to start doing research with my PhD
advisor, Victoria Meadows, who is now also an astrobiologist. And astrobiology is a fascinating
study of the origin, evolution, and extent of life
in the universe. And it's an incredibly interdisciplinary field, bringing together
these chemists and computer scientists and astronomers and physicists to answer these
fundamental questions about life in the universe. And that's kind of the connection sort of to
Earth-like planets that you were talking about,
where the search for life is this sort of fundamental long-term question that exoplanet scientists get to try to answer using the study of exoplanets. And as an astrobiologist and with
the focus on the search for life, that is really thought to be something that needs to be conducted on Earth-sized planets,
sort of following the way we think life developed here on Earth and what life requires to exist,
sort of takes us to these small rocky planets.
Yeah, it's going to be interesting when, you know, in the far future, when we've established
that these rocky planets have life on them to try to explore what other worlds might have life as well.
But you know, start with what you know, then build on that. So you're part of the team that
confirmed the detection of this planet called LHS 475b. But this is just the first step in a
broader program for the James Webb Space Telescope to try to hunt for these Earth-sized worlds and
study their atmospheres. And, you know,
in order to do this, your team looked through data from the transiting exoplanet survey satellite
that hunts for planets. You had all kinds of options. Why was this the planet that your team
decided to go for out of all the different worlds you could have explored? Yeah, that's a great
question. And I will say that it's one of
five planets that we have in our Cycle 1 program to search for atmospheres on small rocky planets.
And so it sort of made the cut in terms of a handful of planets that we're interested in.
And so this planet is, you know, it was hinted at, it was a planet candidate prior to our
observations, indicated by the TESS satellite, like said. And so, we had a sense for when we would need
to observe a star to see it transit and to be able to confirm its detection. And the planet itself,
we knew would be around 600 degrees, and that's much warmer than the Earth. It's not in the
habitable zone. Part of the motivation for this planet is that we are trying to understand the limits of which planets have atmospheres and which don't and what processes drive atmospheres to be lost from Earth-sized planets so that we can put together these physical processes and make better predictions ahead of time when we detect planets about which ones we
think might have atmospheres. And then also to just further our general understanding of atmospheric
science and exoplanet science through the whole population of planets and whether or not they
have atmospheres. So, this is a good candidate for that because it's not by any means the hottest
exoplanet we've ever seen. It's less than 1000 Kelvin, which
winds up sort of putting it in sort of a warm regime. You know, astronomers were kind of fast
and loose with our terminology, sometimes calling things hot and warm and cold, relative to
perceptions that we might have, not necessarily the extremes. And so, this planet is kind of on that boundary, we think, between
very well could have an atmosphere. It's only a little bit hotter than Venus, and Venus has a
very thick atmosphere. And it's not so hot that we really think the star would strip away the
atmosphere.
So, there's a good chance there. Well, we'll get into those details on the atmosphere in a little
bit. But I wanted to ask, just for the people who aren't super familiar with planet hunting,
how can you use a telescope like James Webb Space Telescope to find planets? And why is it so
particularly tricky to find a world of this size that's so small?
The trick to finding exoplanets with current astronomical telescopes and techniques is to indirectly detect their presence.
And the most common technique to indirectly detect exoplanets these days is to see them pass in front of their star and block a tiny amount of light.
And so that method is called the transit technique because the planet is seen transiting across the face of the star.
technique because the planet is seen transiting across the face of the star. So, it's sort of like if you're sitting in a sunny day and maybe a cloud passes in front of the sun, you can tell
that there's less light or sometimes even an airplane will pass in front of the sun and you
just see a quick blip and a drop of light. And then you look up and you see, oh, a plane just
flew in front of the sun. But here we're looking at planets many light years away on their orbits around their star,
and they have to be aligned in such a way from our point of view and their orbital plane to pass in
front of their star. And that's not a guarantee. So there's just a small probability that any given
exoplanet in orbit around its star will transit. Despite that caveat, we're finding thousands of
exoplanets using this method.
And so it's really exciting. And the Transiting Exoplanet Survey Satellite test is so good at
doing this initial search to find planets because it has a broad field of view and it stares at many
stars for many days in a row looking for these planet transits. And so, it covers a large portion of the sky and can
just conduct this broad survey. Whereas JWST is more, you know, you can think of it like it zooms
in a little bit. You know, it's able to do these deep dives into specific narrow corners of the
sky, whether that's looking at some of the most ancient light in the universe or looking at some
of the closest stars to try to find molecules
in those planet atmospheres as they pass in front of the star.
And you did say, you know, with TESS, it has the ability to look at so many stars for so many
worlds at a time. But I would think what's really impressive here is that you not only managed to
take like one detection on this planet, but with just two transits, you were able to learn all
kinds of things about this planet. And luckily enough, it's close enough to its star that it orbits
quickly enough that you saw it during those two transits. And they were only four days apart,
right? That's right. Yeah. So we were able to catch two independent transits four days apart.
It's on a two-day orbital period. So there was one opportunity in those four days where we didn't catch it, but
that is okay. And the two observations with JWST were so consistent with one another. And that's
one of the amazing things about working with JWST data is just how reproducible the observations are
if you go back and observe the same thing twice. It's extremely stable. And there aren't these
systematic errors that sometimes crop up
when telescopes are changing temperatures, which can happen if they orbit the Earth and pass
into the shadow of the Earth and then back into the sun. That can change aspects of the telescope's
operations and whether you're getting the exact same data. Scientists have to correct for stuff
like that, and it gets complicated. But with JWST, the data is extremely
clean. The second we download it, of course, we still have to process it and run models to get to
our final result. But ultimately, seeing those two transits was like the first step in confirming the
detection of this planet. Yeah. And because that data is kind of, you know, so clear, I'm sure,
you know, your error bars on'm sure, you know, your error
bars on this are way more narrow. You actually can really get in there and try to figure out
details like, is that an atmosphere? You know, maybe I'm just still tripping out over this,
but the fact that we can even do that kind of science at all at this point just, you know,
underscores how amazing this new instrument is. How many years have you been looking forward to
using this telescope to do this? Many years. Of course, I'm still an early career scientist. So there are some folks who have
been around since the early stages of planning for JWST when there were only a handful of exoplanets
that had been discovered. But I did calculations in grad school predicting the capability of JWST and thinking, okay, well, this should be capable of sensing the atmospheres of small Earth-sized planets around the very smallest of stars.
And just to see that it is meeting those requirements right now and even exceeding pre-launch expectations in some senses, that is an extremely good sign for amazing science to come.
And I think that's one of the major sort of takeaways from our work here is the forward
looking perspective that these data are so good, it's expected to be taking data for now,
well over 10 years, maybe can last 20 years, that just will bode really well for amazing discoveries.
Oh, fingers crossed. You know, it's learning so much about exoplanets, but there are a million
other things that we want this telescope to teach us about our universe. And the longer we can keep
it up there and working, the better, because I will be so sad if it ever stops working. I'm still
trying to grapple with the fact that someday Hubble will stop working. I'm not emotionally
prepared.
Yeah. But you know, there
are a slew of instruments aboard JWST. And you specifically use the near infrared spectrograph
in order to take these readings. Can you tell us a little bit about you know, what that instrument
does and why it's so useful for studying atmospheres? Yeah, so JWST has all these
different instruments and different modes for each instrument. It's kind of like looking at this giant menu and being excited about all the different options.
And it just blows out of the water the options that were available for exoplanet science with
the Hubble Space Telescope, which is still a very capable space telescope 30 years later.
And so we chose the NIRSPEC instrument partially because of the wavelength
range that it covers in the electromagnetic spectrum. We knew that we wanted to target
molecular absorption features in a potential atmosphere of this planet. And fortunately,
from laboratory studies here on Earth of molecules, we know exactly what wavelengths
each molecule absorbs. And so we specifically were targeting wavelengths
where we'd be sensitive to methane and carbon dioxide, two very common molecules in the solar
system that are kind of the two forms of carbon. If you have carbon, you're likely to have it in
methane or carbon dioxide. Of course, there's many other molecules out there. Those are just
extremely common, and they're both covered in this wavelength range that we targeted. Also,
the stars tend to be quite bright in the near-infrared where NIRSPEC covers. And so,
brighter star leads to brighter backlighting when the planet passes in front and blocks the light.
So, you're going to get better quality data than, say, choosing longer
wavelength observations. And then finally, the near spec instrument has like the highest sensitivity
than all other instruments, or at least in the near infrared wavelength range. So it kind of a
few different lines of reasoning came together for that choice.
It all makes sense. You know, it's kind of fortuitous that in this case, the star,
you know, very bright in the telescope, but also kind of auitous that in this case the star you know very bright in the
telescope but also kind of a smaller star it's a red dwarf star correct that's right yeah and
for people following along with the specific details this is an m3.5 it's a main sequence
m dwarf it's about 3300 degrees kelvin so a little over half the temperature of the sun.
And it's, you know, back in my day, but, you know, when I first started doing exoplanet
detection in college, I remember it being, you know, we could only find things maybe Jupiter
size because we needed them to create such a contrast against the star. But in this case,
you know, you're using kind of smaller stars looking for smaller planets with a telescope capable of actually picking up these differences.
I'm wondering, you know, if you did have like a star in the system that was like a
sun-like star instead, would you still be able to pick up an Earth-sized world with this telescope?
Um, it would be much more difficult. Like you mentioned, the contrast between an Earth-sized planet transiting,
blocking the light from a small star is much higher than a much larger star. So, I think we'd
be able to detect the planet's transit to much lower significance, but any hope for searching
for the atmosphere, which is just a really small effect on top of an already small effect,
is hopeless. And so, that's why we're
looking at these smallest of stars, which presents other challenges in that these are very different
from the Sun and challenge our understanding of what the planets might be like. But at the same
time, you know, it's where we can look right now for atmospheres and any discoveries will expand
our knowledge since we don't know anything about rocky planets and their atmospheres for the small class of stars.
Hold that thought. We'll be right back with the rest of my interview with Jacob Lustig-Yager after this short message from George Takei.
Hello, I'm George Takei. And as you know, I'm very proud of my association with Star Trek.
Star Trek was a show that looked to the future with optimism,
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I want you to know about a very special organization called the Planetary Society.
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When you become a member of the Planetary Society, you join their mission to increase discoveries in our solar system,
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together. So join the Planetary Society and boldly go together to build our future.
We've gone over some of the details on this planet, but let's just do a full rundown. Like, to go together to build our future.
We've gone over some of the details on this planet, but let's just do a full rundown.
Like, what do we know about this world so far from these two transits?
Right.
So prior to our observations, the radius of the planet that TESS was reporting was really,
really uncertain.
It was possible that it was Earth-sized, but it could have been smaller than Mars, and it could have been nearly almost twice the size of Earth, just a huge range of sizes. And because we're looking at the planet transit, it tends to be extremely sensitive to
the radius of the planet. That's the key thing that we're observing with really high precision.
And so, the first thing we're able to update is the planet
radius, which we found delightfully is 0.99 Earth radii. So, it's exactly the same size as Earth.
So, that is just a serendipitous thing. An interesting thing is that we don't actually
know the mass right now. The types of measurements that are required to measure the mass have not
been made yet. And so, we took a look at the population
of M-dwarf Earth-sized planets that had measured masses and radii, and we were able to estimate
what the mass of this planet might be if it shares many characteristics with that population
of M-dwarf rocky planets, in which case, they tend to be slightly underdense relative to the Earth.
So we think its mass will be maybe around 90% that of Earth,
but there's a broad range of uncertainty on that.
So it could have more iron in its interior than Earth
and end up being heavier than Earth's mass,
or it might have a larger water fraction than Earth.
That could lead to it being less dense than Earth.
I've got to ask, you know, because 99% is really close to 100%.
And how does that compare to all of the other Earth-sized exoplanets that we've found so far?
I don't know if I've heard of one that's 99% the radius of Earth.
That's wild.
I, you know, I don't know. I haven't heard of one off
the top of my head that is as close to being Earth-sized. And of course, you know, I gotta
say again that it's much hotter than the Earth. It is very different from Earth in probably every
other way, but it just happens to be Earth-sized. And that also, you know, that's a very cool
characteristic to share. There are all kinds that also, you know, that's a very cool characteristic to
share.
There are all kinds of things that could play into that temperature there. And I've got some
questions about that. But I mean, the primary reason is probably just that it is so close to
its star, and it's not really in the habitable zone, right? It's a little too close to its star
for that to be true.
Yeah, it receives about 20 times the amount of light from its star than Earth
receives from the sun. So that puts it well interior to the habitable zone and hotter than
Venus, actually, at least without knowledge of any atmospheres in either case, because Venus is a
very interesting case in terms of an atmosphere. Yeah. And, you know, you guys did try to figure out whether or not
this thing has an atmosphere, but you weren't exactly able to answer that question just yet.
So what do we know about this planet's atmosphere if it does exist?
We were able to take our extremely precise measurements and they ruled out really extended
atmospheres that are composed of hydrogen and helium.
Those tend to be the easiest for astronomers to rule out first because these type of atmospheres
that are similar maybe to Jupiter or Saturn's atmosphere, that they're composed of really
light molecules with smaller amounts of other gases like methane, carbon dioxide, carbon monoxide,
water. But when you have light molecules in an atmosphere, it tends to make that
atmosphere way less and it can extend more out. And since again, we're measuring the radius of
the planet here, and we're looking for the signs of molecules and the way they make the radius of
the planet larger at specific wavelengths where the atmosphere absorbs light. And this is the
method of transmission spectroscopy
that we're using here. And hydrogen-dominated atmospheres would have shown up in our data
at like night and day. We would have seen massive spectroscopic features from hydrogen and helium
causing the atmospheres to be extended. And we didn't see that at all. We measured an incredibly
precise, very flat line. And so, we can throw out all the possibilities that involved hydrogen and helium in this
atmosphere.
Now, we are able to weakly disfavor a model that has, say, a pure methane atmosphere.
Methane is much heavier than hydrogen and helium, but a lot lighter than some of the
other molecules that we considered.
And that tends to have a bit more of an extended atmosphere as well. And I already
mentioned that we kind of targeted this wavelength range specifically to be sensitive to methane and
carbon dioxide. And so we don't see a methane feature in our spectrum. And so that leads us
to disfavor that pure methane model, but it could still have an atmosphere where the bulk of
it isn't made of methane, but it still has some methane in it. And then sort of the most difficult
thing is that if we take a look at a pure carbon dioxide atmosphere, similar to that of Mars or
Venus, we also get a spectrum that would be a flat line, just like we measured. So we don't have the
precision from these two observations to distinguish between a pure flat line, just like we measured. So we don't have the precision from these two observations to
distinguish between a pure flat line that would be the result of a completely airless world with
no atmosphere and a Mars-like or Venus-like atmosphere with 100% carbon dioxide. And so
it's going to require further observations to distinguish between those two cases. But I think, you know, while there are other atmospheric possibilities besides like a pure
carbon dioxide, it provides a really good goalpost to aim for because it is a difficult
measurement to make because carbon dioxide is one of the heavier molecules we'd expect to be there.
It leads to the atmosphere being very compact. And even though it has extremely strong and well-known
spectroscopic features, the compact nature of those carbon dioxide atmospheres just presents
a challenge that will just require more data. Yeah. And that kind of brings me around to the
temperature of the planet because, you know, I always think of atmospheres kind of like
planetary jackets, you know, they hold in some of that heat.
And I'm wondering if that might give us some clues here.
Because if the planet has absolutely no atmosphere, we can think of that scenario, its surface
temperature is going to be mostly dependent on its star and how close it is and how wide
across this planet is.
But in the case that there's an atmosphere, I mean, maybe it's holding on to extra heat
that could give us a clue, right?
Yeah, and that can kind of go both ways, because with Venus and Earth, that's certainly the case where the atmosphere causes the greenhouse effect that allows it to blanket in and trap heat and makes the surface temperature much, much higher than you would expect for an airless body. But on the other hand, these really close-in planets around M dwarfs are thought to be tidally locked and synchronously rotating so that they have a
permanent day side that always faces the star and a permanent night side that never faces the star,
which is a really interesting scenario for a planet and really gets our sci-fi minds thinking
here. And, you know, these planets might be quite a bit different.
And many people study the atmospheric dynamics in such an atmosphere
where you're looking at what direction the winds go
and how might clouds form on the day side?
Do those clouds transfer to the night side?
What's going on?
And so in these tidally locked, synchronously rotating atmospheres,
the models suggest that they have extremely high winds that transport heat from the day side to the night side.
And that kind of acts to cool the planet relative to what you might see for an airless body,
at least on that day side.
So, we tend to be slightly sensitive with a different type of observation.
When you watch the planet pass behind the star at secondary eclipse, you can actually make a measurement of that day side
temperature. And so, these types of recirculation might cool the planet relative to a constantly
heated day side where you'd expect this really hot, rocky surface that is just instantly radiating
that heat back to us and able to be observed.
So, you know, it's a bit more complicated than just the greenhouse effect, but there's really
a path forward for learning more about this planet using JWST, I think.
I do have a question about what temperature we would actually be measuring in the scenario that
it has an atmosphere. Because, you know, with a lot of atmospheres, the temperature varies with its density and its composition and its altitude
in general. I mean, even on Earth, there's a layer of atmosphere way up there that's hotter than in
the layers underneath. So what temperature would we be measuring here in the case of an atmosphere?
Is it kind of like an average across the entire atmosphere?
Yeah, I mean, that's such a good question.
And the detailed answer has a lot of nuances and requires modeling.
But the kind of the key is with an atmosphere, you're measuring a different temperature as a function of wavelength,
because different wavelengths of light are able to probe different depths into the atmosphere or really like the region from which light emerges is dependent on
the actual temperature structure of the atmosphere like you're saying how the temperature varies with
altitude and the way that the gases within the atmosphere interact with light and so those two
effects combine in a complicated way that requires numerical modeling and computer simulations to
do in detail. But it is exciting because the spectrum of a planet's thermally emitted light
doesn't just tell us about the molecules that are there and how much of them there might be,
but it tells us about the actual temperature structure of the atmosphere, which is something
that JWST is really capable of doing
for larger planets. And so I'm really looking forward to my colleagues' results coming forward
in the next, I don't know, year, couple of years, studying the temperature structures of all of
these hot Jupiter planets and super-Earths, because it'll be these altitude-dependent
studies of these really hot planets. And so we're not quite there for Earth-sized planets. I think
either it will take a large amount of time with JWST or even future observations to be sensitive
to thermal emission from them because they are, you know, Earth-sized planets are small. And
particularly if we want to be studying those that are in the habitable zone, they're just cold,
relatively cold, and colder things emit less
thermal light.
Yeah, it is.
It's a complicated situation.
It is.
You're going to be observing this object more in the future.
I know there's at least one planned observation sometime this next summer.
Do we think that that's going to be the end of the research on this planet with JWST?
Or is it like,
kind of see how much information you get, gauge whether or not you get the answers you want,
and then follow up in the future if you need to? We're definitely excited about the follow-up observation, the observation that we already have planned as part of this program in July.
And that will kind of add to our current study. We'll revisit the target with all three observations
and kind of update our results at that point.
But I think there are huge opportunities
to continue using JWST to observe this target.
I tend to think that the thermal emission route
from the day side is a critical way to get a sense
for whether that suggests that the planet has no atmosphere
or a thick atmosphere.
And if it has,
if those measurements are to hint that it does have an atmosphere, then I think it would be a really strong motivator for observing more transits to try to go after the more compact
carbon dioxide atmospheres, because the thermal emission could give us a sense that there's an
atmosphere to continue observing. But if it's an airless body and the thermal measurements show that, then I think it might
be the end of JWST observing this target just because there are so many more targets and it
kind of gets to the core goal of just figuring out whether these small rocky worlds around
these small M-dwarf stars even have atmospheres. It's sort of a win-win whether or not they do or
don't. If they do have an atmosphere, of course, there are more follow-up opportunities to learn
more. But if they don't, they kind of go into that, the bin of those that don't have an atmosphere
that together with that whole population will allow us to hone our understanding of planetary
science. Yeah, because there's a good chance that,
you know, stars of this type with planets at that distance, just, you know, maybe the star
blows the atmosphere straight off of them. So knowing more about this group will be useful
in the future. But I know that part of what you guys are trying to figure out with this thing is
whether or not it has clouds in the atmosphere that could give us an indication that it's more
Venus-like with more carbon dioxide.
That's just kind of blowing my mind a little bit. I know we've detected clouds on other planets,
mostly bigger, puffier planets, but with a planet like this that's orbiting its star so quickly,
and as you said, might be tidally locked and having these raging winds whipping around it,
how would we detect clouds on something like that?
It's a tricky thing to do. You know, there is a history of clouds kind of obscuring what we're seeing in exoplanet atmospheres. And it goes back to the hot Jupiters and super-Earths.
Basically, a cloud deck has the effect of limiting our sensitivity to absorption features from
molecules in the atmosphere. With gas giant planets,
where there's no question whether or not they have an atmosphere, they must have an atmosphere
to be as large as they are. When we see very small absorption features from molecules,
it implies right then and there that there is a cloud deck blocking our view to the lower
atmosphere. And of course, our knowledge of the solar system,
we can look right at Venus and say, well, Venus's atmosphere is incredibly difficult to see the surface. It stumped scientists for hundreds of years, and it required very particular observations
to understand the lower atmosphere of Venus. And so there's kind of that solar system example of
not being able to see the lower depths of an atmosphere.
And we are really going to face that with exoplanets, particularly rocky planets.
We can't take for granted that they have an atmosphere.
There are a lot of reasons why they might not.
And we just don't know.
Certainly, our observations are a candidate for clouds explaining why we didn't see anything.
Of course, it could just be a thin atmosphere like
Mars as well. And it's so difficult to see, are we blocked because we're just seeing the rocky
surface or are we blocked by a cloud? And that's where these thermal measurements, when the planet
is at secondary eclipse, is kind of the optimal path for disentangling those two effects because
the clouds are highly reflective and that's
another aspect of them that tends to cool the planet. Planets maintain this sort of balance
of energy between the light the star shines on them and how much of that light they're able to
hold within them and allow to heat up in a very high, we call it high albedo body, but like a very
reflective planet perhaps because it has
clouds, is able to reflect all that light back to space and only be minimally heated up. And so,
that stands in huge contrast to a planet that has no atmosphere and might have a rocky surface,
like Mercury or the Moon, that are really dark. These rocky surfaces tend to be dark,
or the moon that are really dark. These rocky surfaces tend to be dark, and so they absorb heat really well. And so, again, this is a key path, I think, to answering these next level
questions about this target. And I think that's probably the way to go and the way our group
hopes to continue studying this planet with JWST.
And I think you said this earlier, but it's just, you know, one of what, five planets that you guys are planning to explore. So when are we going to be hearing more about these other worlds you're going to be looking at?
later, it transited again. So we have two observations of a second target we're looking at.
And so we're working on analyzing those data. It's way too early to say,
you know, we have that target coming down the pike and then another target, two targets being observed late February and early March. And then a final target, TRAPPIST-1H actually,
one of the interesting TRAPPIST-1 planets, will be part of our program
observed, I think, one observation this summer and then two more in the winter. So, it's sort
of like the next year we'll have JWST periodically looking at the planets from our program. You know,
it's not just our program. There's tons of exoplanet science going on with JWST and many
colleagues of ours having other programs going on, other exciting rocky planets, the other TRAPPIST-1 planets.
So I think it's going to be a really exciting continuation of this first year of JWST data and then lots more exciting stuff to come.
Oh, yeah. I'm so glad that you bring up the TRAPPIST-1 system because I know that you've done some work on this in the past before JWST ever launched you know this system seven earth-sized
planets many of which are in the habitable zone this is just you know
it's like the holy grail of planetary searching astronomy right here there
might be so many things in that one system and it makes me really happy to
know that you're gonna get to do some of that work knowing that you've already put in so much effort into learning about that system. So that
brightens my day to hear. I'm so glad. Yeah, it's a fantastic system. I think it's probably my
favorite, although it's probably worth reconsidering what my favorite system is now that we've played
a role in confirming the discovery of LHS 475B. But the TRAPPIST-1 system is just undeniably compelling with those seven known
relatively Earth-sized planets. Two of them are well interior of the habitable zone at HOT.
One of them is kind of on the border of the habitable zone. One is definitely outside the
habitable zone, too cold. So within one planetary system, all of the planets are sort of spanning
the breadth of this classical habitable zone that we've created from models of the planets are sort of spanning the breadth of this like classical
habitable zone that we've created from models of the solar system and extended those really
cleverly using sophisticated techniques to other stars. But it's really this opportunity to
test that, whether that habitable zone is in existence there. Can we find evidence that these
planets have conditions that could be favorable to the origin of life.
And they're an opportunity to search for biosignatures with JWST.
But we're asking a lot of this one system because it's also a really, really small star.
It's Jupiter size.
And it's an active star.
It's flaring.
And it presents some challenges both to the existence of atmospheres on these planets
and the long-term potential habitability on the planets in the habitable zone.
TRAPPIST-1H, I'm thrilled to have it as part of our program because, like I said, we're trying to
understand the boundaries of which planets have atmospheres and which planets don't. And this is
a particularly cold planet, one of the smallest, coldest planets that's known.
And to be able to search for its atmosphere provides really a nice contrast to these warmer planets that are sort of going first in our program. And so, it sort of is just comforting
to me that we have these warm planets and we have a cold planet in there too,
to just sort of spice things up.
Yeah, just a wide range of things to explore.
I mean, it's a whole galaxy of planets out there to start looking at.
And we're only just beginning.
And I'm so thrilled that we're in this new age.
But it does make me think, you know, we've been waiting for this new telescope for ages,
and we can finally begin to do this research.
But what do you think that we're finally going to need
to really definitively look at worlds and say that is a twin of Earth?
Because we're getting close, but we might need a little bit more
or maybe more telescopes just dedicated to this question.
Yeah, I think that's the key there is JWST is going to allow us to embark on this path
and study Earth-sized planets. But
when it comes to planets in the habitable zone, you know, we're probably going to be able to get
a sense for molecules in the atmospheres of a few habitable zone planets around these very,
very small stars. But, you know, JWST is going to tell us what atmospheres are like around
Earth-sized planets and larger planets,
but particularly Earth-sized planets around these small stars. And we still want to know about other
types of stars. There might be aspects of these small stars, like the proximity of the planets
to them, their flaring, that make a search for life challenging or the existence of life hard
in these systems. And it's important that we're able to,
in the future, also be able to study more sun-like stars. And so, I do think NASA has now
embarking on a plan to develop this habitable worlds telescope that has been discussed recently
and was prioritized by the 2020 Decadal Survey, this 10-year study that the community of astronomers does to figure
out a consensus path for the next decade. And there's considerable effort behind this
next-generation telescope that will build on the successes of JWST. It will be designed to have
this sort of hexagonal pattern of segmented mirrors. It'll be designed from the ground up
to study the atmospheres of Earth-like planets in the habitable zone of Sun-like stars. And
it will just take things to the next level. And it's, I think, what we'll need to conduct
a rigorous study in the search for life on these habitable worlds and to sort of not put all our
eggs in the M-dwar dwarf basket, as it were,
because these systems are challenging, not just to study and interpret, but to imagine long-term
habitability. And, you know, it might be a long time before that telescope is done. I think we
all learned that lesson waiting for the James Webb Space Telescope to happen. But I think this
telescope has proven, if anything, that it was
worth the wait. And so will this new generation of telescopes. So I'm so excited. We're just right on
the cusp of so many amazing discoveries. Yeah, I'm excited too.
Well, all kinds of new planet finding to do and look forward to out there, Jacob. And I really
want to thank you for joining us today. And please send our congratulations to the rest of your team for this discovery.
It's got to be just such a great feeling.
Well, thank you so much for having me.
It's been a pleasure.
Sometimes when I'm looking at the sky, I think about all of those distant worlds,
places no living creature has seen, and how beautiful it is that here we are,
peering out into the universe with curiosity and optimism,
wishing to know those places and searching for the familiar among the stars. Who knows what we'll
discover next as JWST continues to look deeper into space than ever before? With that thought,
here's the Planetary Society's chief scientist, Dr. Bruce Betts, to share what's up in the night sky.
chief scientist, Dr. Bruce Betts, to share what's up in the night sky.
I am back once more with the brilliant Bruce Betts. You like the alliteration, Bruce?
I do. I'm with the stupendous Sarah.
That counts. That works.
All right. I'll work on that.
Well, bright and brainy Bruce, bringer of banter uh what's up oh my gosh i'm caught so off guard let's get into what's up in the night sky how about that we've got that comet
comet ztf c slash 2022 b3 that is tough to see if it's even possible to see with the naked eye
but maybe from a dark site and certainly with some binoculars or a telescope, you can see it at least as a fuzzy blob.
And that is hanging out in the north.
So it's actually good for the northern hemisphere right now.
It's terrible for the southern hemisphere, but we'll cross farther south in the next couple weeks.
So I suggest you find a finder chart online.
We've got a nice article
on our website about the comet. It is beautiful and green and the like if you take long exposure
pictures with a big telescope. And so there are great pictures of it.
Yeah, already I've seen some amazing images from some of my friends. I'm so excited.
Yeah, no, it's very cool. There are some time lapses where you can see the gas is coming off, the dust coming off. We've also got our friends, the planets, Venus, now hanging out with us for a few months over in the west, anytime after sunset in the early evening. And above super bright Venus is really bright Jupiter growing closer and closer together over the next month until they're very close together on March 1st.
If you follow a line from Venus to Jupiter across the sky, you will reach Mars looking reddish, and it's good stuff.
All right, we move on to this week in space history.
It was 1971 when Apollo 14 landed humans on the moon,
and some people view most significantly when Alan Shepard hit golf humans on the moon. And some people view most significantly
when Alan Shepard hit golf balls on the moon.
When I was a kid, I thought that was something
that was just like from cartoons.
And when I finally saw images of that, I laughed really hard.
Yeah, no, it's quite funny.
We move on to random space fact.
Speaking of, which we're not, not well we actually are with golf balls one of the unusual things to have flown in space was the baseball home plate from shea stadium of the new
york mets it flew on a space shuttle sts-120 in 2009 just as the mets moved from shea stadium to
their new stadium where it's now on display,
to fit in the shuttle locker where they carried such items, you know, home plates. Mike Massimino,
the astronaut, had to remove the outer black edges of it, and then they were put back together when
they got back to Earth. If you are a Yankees fan, don't worry. 2008, dirt from the pitcher's mound of Yankees Stadium was flown on a space shuttle.
That's funny.
I bet you could write an entire book about all the strange things that have gone to space.
Let us move on to the trivia contest.
And I ask you, whose voice was the first to be broadcast from space?
How'd we do?
We got a lot of answers for this one.
Most of them were right.
Some people did get confused on this one
and thought we were asking them
for who the first person in space
to send a message was.
But the answer was actually
U.S. President Dwight Eisenhower,
who on December 19th, 1958,
sent a Christmas message
that was broadcast
by the Signal Communication
and Orbiting Relay Satellite, or SCORE.
Score!
Score!
Yeah, and it was a really lovely message, just kind of about, you know, the United States
wishing everyone peace on Earth and goodwill.
So that was nice.
Yeah.
Well, way to go, Ike.
And our winner this week is Judy Inglesberg from Mount Laurel, New Jersey.
And Judy, you will be receiving a beautiful
2023 International
Space Station calendar. So, you know,
maybe somewhere on there will be pictures
of weird objects people have sent to space.
No, I checked through it.
It doesn't have any of that stuff. It's just beautiful
ISS picture.
But we did get a lot of messages
from listeners on this one,
particularly about the SCORE satellite.
This one cracked me up.
So one of our previous winners of the trivia contest,
Eric O'Day from Winchester, Massachusetts, wrote,
some of these old satellites looked cool, but SCORE,
it looked like the back of someone's refrigerator fell off.
No style at all.
Well, that's a funny image.
I have to look it up now.
No, I did.
I looked it up and he's right.
And we also got this great topical limerick from Jonathan Gorbach from North Virginia, USA, who wrote,
From a relay above in the night came a voice that was measured and bright.
Warm felicitations to all of Earth's nations.
Score one for President Dwight.
Oh, nice.
Very nice.
It was nice.
Got anything more or shall I move on?
Yeah, I did want to share one more message, which really kind of, you know, put a smile on my face.
Joe Hsu from Corpus Cove, Texas, wrote in, I'm an exchange student from Taiwan. My host parents and
I like space. We usually listen to your podcast together when we're in the car and we really
enjoy it. Though I can't understand much, I still like it. So thank you so much. And that makes me
really happy to hear because my family used to host exchange students when I was a kid. And
there's just so much that we can learn and share with each other, whether or not it's about space or different cultures and languages or just about each other in general.
So I wanted to say thank you, Joe, for listening to the show.
And I hope you have a really great time while you're visiting Texas.
All right.
You ready to move on?
Yeah, let's do this.
All right.
In our friend, Comet ZTF C2022b3. What does ZTF stand for? Go to planetary.org slash radio contest.
Nice. And we'll be selecting just one winner for this one, but they will be receiving a copy of a
book called The Year in Space by the Royal Astronomical Society's Supermassive Podcast.
Other great space podcasts out there. It highlights all of the
really exciting things that happened last year in space, including what happened with the James Webb
Space Telescope. So if anybody wants to enter, you have until Wednesday, February 8th at 8am
Pacific time to get us your answer. And you'll want to go to planetary.org slash radio contest.
All right, everybody, go out there, look up the night sky,
and think about the optimum design for a can to maximize the volume while minimizing the surface area.
Thank you, and good night.
Thanks for joining us this week on Planetary Radio
as we continue to marvel at our place in space.
Come back next week for a dose of new Martian discoveries with Mars expert Tanya Harrison.
Planetary Radio is produced by the Planetary Society in Pasadena, California,
and is made possible by our stellar members.
You can join us as we continue to explore worlds and search for life at planetary.org join mark
hilverta and ray pauletta are our associate producers andrew lucas is our audio editor
josh doyle composed our theme which was arranged and performed by peter schlosser
and until next week ad astra