NASA's Curious Universe - Sun Series: The Sun, Our Star
Episode Date: March 19, 2024The Sun is our closest star. Billions of years ago, it shaped the formation of our home planet and the beginning of life on Earth. Today, it provides the heat and energy that powers our civilization, ...but it can also disrupt our technology and spacecraft through explosive outbursts of radiation. Join NASA Sun scientist Joe Westlake on a journey from the surface of Earth to the Sun’s core to learn how intricately we’re connected to our star and the progress we’ve made unraveling its mysteries. This is episode one of the Sun and Eclipse series from NASA's Curious Universe, an official NASA podcast.
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This is NASA's curious universe.
Our universe is a wild and wonderful place.
I'm your host, Patty Boyd.
And I'm your co-host, Jacob Pinner.
And in this podcast, NASA is your tour guide.
From here on Earth, the sun can seem a little boring, or at least predictable.
It's a big, docile yellow ball up in the sky.
It rises and sets every day right on schedule.
Well, we're here to make you see the sun in a whole new way.
If you zoom in closer, our nearest star is an incredibly dynamic place,
full of swirling magnetic fields and explosions of plasma that rocket out into space in all directions.
And right now, in 2024, the sun is near solar maximum, which means it's at its most active and stormy,
sending explosions of space weather towards Earth that can disrupts the technology that we take for granted,
both up in space and right here on the ground.
This year, the sun is making sure we know it's the star of our solar system.
So we're bringing you something special in its honor.
A five-part Curious Universe miniseries about all things solar.
For the next five weeks, we'll be bringing you the stories of daring NASA missions like Parker Solar Probe.
Lift-off of the mighty Delta 4 heavy rocket with NASA's Parker Solar Probe.
Which is overcoming incredible odds to touch the sun and unravel some of its biggest mysteries.
You'll meet people obsessed with auroras and eclipses,
voyaging across the world, braving icy blizzards and baking hot deserts
to catch fleeting glimpses of our sun's power right here on Earth.
We'll take you into the path of totality for the otherworldly experience that is a total solar eclipse.
Wow!
Wow!
And inside the NASA control rooms where heliophysicists or sun scientists
forecast space weather risks to our astronauts.
These stories will change the way you think about our nearest star, I promise.
And so to do all that, we're bringing the whole team together.
You'll hear from me.
Me.
And me.
That's Christian Elliott, Curious Universe producer.
Hi, Patty.
Hi, hi, Jacob.
In this episode, Christian, you said you're bringing us the most important story of all.
Our son's superhero origin story.
The story of how a star is born, how it shapes and mold.
the solar system and planets and how it makes life on Earth possible.
Christian, that is a lot to cover.
So where do we start?
Well, how about the very basics?
Sun 101.
I mean, what exactly is the sun?
Ooh, that's what isn't the sun, right?
For that hard-hitting question, I went right to the top.
Yeah, so my name is Joe Westlake.
I'm the division director for heliophysics at NASA headquarters.
So you asked NASA's director of Heliophysics what the Sun is?
Yes, I did, Jacob.
That's the great thing about working at NASA.
You get to ask very smart people questions like that one.
But anyway, Joe is a great person to explain the Sun to us.
He's new to the job at NASA, but he's worked on nearly every aspect of space science that you could think of.
He was on the team that helped discover the Higgs boson, a new elementary particle in physics.
At a laboratory in Europe.
He's studied Saturn's moons,
Titans Upper atmosphere.
It's a really fascinating place.
Earth's magnetosphere.
The magnetosphere, our home here on the Earth.
So, anyway, back to the big question.
At the most basic level, the sun is a giant ball of gas and plasma.
That is sort of the fundamental life force
or the fundamental source of energy in our solar system.
It's a great energy source because of all that gas,
mostly hydrogen,
huge gravity of the sun.
The hydrogen is, you know, undergoing this like,
this fusion to go into helium, so you're fusing atoms together,
creating energy and doing that.
That energy comes out as light and the light that we see,
you know, when the sun comes up.
That's all true for our sun, but it's actually true
for most stars most of the time.
The important point here is that the sun is a star,
just like any other.
It just happens to be our closest star.
Right, yes. When you look up at the night sky, you're looking at a sky full of faraway suns, of a vast range of sizes and ages.
Our sun is a fairly average, you know, main sequence star. You can find a similar one in many places within our galaxy.
So what I'm hearing here is that we aren't special?
Well, yes and no. It might be an average star, but the sun is just right for us.
If it was a much larger star, if it was a much smaller star, if it had much more mass, much less mass, we might not have the same situation at the Earth, may not be as habitable, might not be as unique of an experience here for humanity because our sun may be more violent, maybe less violent, things like that.
Our sun is definitely just right for us. But since it is a star, just like all the others, just light years closer to us, we study it here at NASA to both better underwomeness.
understand how it affects us and to better understand how stars elsewhere in the universe work.
Right. Patty, you're an astrophysicist and you're focused outward from our solar system usually
toward other stars and exoplanets. But it turns out we kind of have astrophysics here at home, too,
in our own backyard. We just call it heliophysics.
Huh. So just to recap, we have this star, and it's the same kind of star that we can see all across
the night sky that have planets of their own, but it's right here in the middle of the solar.
system, keeping Earth nice and toasty and hospitable.
I guess my next question is, how did it all start?
How did we get here?
Well, that is a very good question, and to answer it, we're going to go way back.
Now, imagine where our solar system, our sun, our Earth is now.
It's just completely empty, just the black void of space.
Well, it's not completely empty.
There's some dust and gases floating around.
But what happens is that you get sort of collections of gas.
These collections of gas basically are gravitationally bound to each other.
So the gravity pull of large masses of gas is pulling these particles together.
And eventually you end up with enough to where they're pulling in so much more gas, so much more gas.
And the things that are getting packed into the inside are getting so close together that they're,
that they really can't keep themselves apart.
And then you start to do undergo fusion,
and that star is ignited.
So a star ignites in space, that's the beginning of our solar system.
But what about all the other stuff that's around the sun today?
Like, when does Earth come into the picture?
Well, in general, once you have all the mass of the star in one place,
all the leftover gas and bits and bob start to orbit around it.
And they pick up speed and momentum.
Yeah, that's exactly what Joe said.
get this kind of disk of gas and dust orbiting the sun.
As this gas goes around and starts orbiting the sun, you end up getting like clumps, right?
Some of the perturbations as they come together turn into these larger perturbations,
you know, larger fluctuations, larger changes in that local gravity.
Things start to collect together and stick.
So we're living on a, what was that word he used?
a perturbation, like a clump of matter.
The third farthest collection of matter from the sun in our solar system.
Basically, yeah, those clumps of gas and matter orbiting the sun turn into Earth and into all the planets.
And there's a lot that happens over billions of years to make our Earth what it is today, of course.
But the biggest factor all along the way, the reason why we're here at all is the sun.
Obviously, you need gravity.
Otherwise, we would float off into our own area
and probably not be near a star, be very cold.
So the gravity of the sun that has kept the Earth in close
has created an environment that's useful for us.
And again, the sun is putting off just the right amount of energy,
photons that bring light and heat to Earth
to keep our planet's surface under the right conditions for life to begin.
And where a planet is with respect to its star really matters.
The Earth is in like this perfect position with respect to the sun, something we call the habitable zone or Goldilocks zone.
And what that means is that once life got a foothold here on Earth, it could spread and thrive and evolve.
So at this point in the story, we've got Earth.
We've got life, which is starting up because of the sun's warmth and light.
And then humans show up and we start to build civilizations, right?
Right.
And we've been looking up at the sun and wondering about it and thinking about it.
ever since.
It's pretty wild if you think about it, just how impactful the sun has been.
It's made agriculture possible for one, which let us settle in cities and develop civilizations
all around the world.
And at the same time, we have the sun to thank for calendars, our sense of time and seasons,
basically all the rhythms of our life here on Earth.
And wherever you look, the sun shows up over and over again, in literature, music, religion.
By looking at the sun through telescopes and observing its influence on us through the aurora,
eclipses, and more, we as humans, learned more and more about how it works over the centuries.
And our understanding of the sun really advanced when NASA came into the picture.
All at once, Americans were interested in the oncoming age of space.
And with the curiosity came a mounting, swelling demand to get a satellite into the air on the double.
So, to set the scene, it's the 1950s, it's the 1950s, it's the world,
the space age, we've got rockets and satellites, and we can go into space, and scientists are
eager to study all the bodies in our solar system and beyond.
Cosmic ray intensity, meteor impact, solar radiation. These are the dry facts that will help
carry man ever father in the age of space. We've had a long history of observing the sun.
It dates back, you know, before the United States was formed, right? We've observed the sun.
but observing the sun from the space has happened really since the beginning of the space age.
And there's been a lot of discoveries that have happened since the beginning of our space-faring race.
Studying the sun has sort of defined NASA's history.
Understanding our star was a goal for space science even before NASA formed,
so there have been a lot of missions.
Right, studying the sun has been a huge focus for NASA for decades.
There's a whole fleet of heliophysics spacecraft, and they're spread out in strategic places between the sun and Earth and even into the interstellar medium beyond our solar system.
So from all of these missions, we've learned that the sun and its relationship with the Earth is more complicated than we thought.
Hmm. Complicated how?
Well, first we really have to understand the Sun. It's got layers, literally. So let's start by zooming all the way in.
At the very center of our sun is its core where those nuclear reactions happen, that fusion
that releases the sun's energy.
Then we've got the radiative zone and the convection zone, two layers where the plasma
and magnetic fields are swirling around and up toward the photosphere where the sun's light comes
from.
If you were to stand on the surface of the earth and with your protective eclipse glasses
on, look up at the sun, you see the photosphere, you see where the photons are coming from.
That's relatively cold.
Cold, yes, but still pretty hot compared to Earth,
coming in at over 6,000 degrees Fahrenheit.
Right, but that photosphere is actually not the sun's outermost layer, or its hottest.
That honor goes to the corona, the sun's crown, its outer atmosphere.
And the corona is a really wild and mysterious place.
It's way, way hotter than the photosphere.
What happens is that as you come from this photosphere out into the corona,
you get this intense, you know, warming, intense heating of the particles in plasma.
Yeah, that seems like a puzzle.
I mean, if the core is the hottest part, as you move further away from that,
you would expect it to get cooler, right?
I'm picturing when you make a campfire and you sit too close to it and you get hot,
and so what do you do?
You walk away from the campfire, right?
Yeah, it doesn't make sense to heliophysicists either, but it's true.
How it gets so, so hot is one of the sun's biggest mystery.
And a big reason why it's mysterious is that you can't see the corona with your naked eye.
From Earth we can only see and study it during eclipses when the moon blocks off our view of most of the sun,
or through the eyes of spacecraft or telescopes.
Yeah, but we can see some of the stuff the corona does,
because this outer atmosphere of the sun is so hot and has so much activity,
it has these huge explosions, these outbursts that we can detect.
It's really like the atmosphere of the sun is blowing off into space
and that atmosphere is so hot, so incredibly hot,
that it then ejects itself off into space,
sometimes violently, sometimes with these coronal mass ejections and things like that.
So coronal mass ejections, what are those?
Good question.
There's actually a couple kinds of explosions or eruptions that come off of the sun.
Now a coronal mass ejection is something where you're seeing
basically a big parcel of gas, a big,
parcel of hot gas being blown off of the surface of the sun.
So there's this explosion on the sun that actually sends material from the sun flying off into
space?
Like an ejection of coronal mass, I guess?
Yes, it's well-named, but it actually gets even wilder than that.
The second kind of eruption is called a solar flare.
A flare is a very explosive event that basically sends off all this energy very, very fast in
the form of high-energy light.
to the Earth.
And coronal mass ejections and solar flares can even happen at the same time.
And sometimes you get it where there's a coronal mass ejection that has flares within it, okay?
But that coronal mass ejection travels much slower to the Earth a few days.
So you've got flares, these quick flashes of energy, radiation that hit the Earth, and then
these coronal mass ejections, which are big chunks of plasma that come our way a lot more slowly
because they have mass?
Yeah, exactly.
Now, remember, you can really just see the photosphere from here on Earth, unless there's an eclipse.
All this wild, chaotic activity in the sun's atmosphere is basically invisible.
But NASA has satellites, like the Solar Dynamics Observatory,
floating out in space, looking at the sun that can zoom in close on that violent activity.
So you can see it for yourself in the imagery.
That satellite is part of a program NASA calls Living with a Star,
because it's about learning to live next to such an explosive neighbor.
Yeah, I think I have an explosive neighbor at my house, too, so I get that.
Yeah, I think we all do.
It's very true.
Anyway, in the imagery, you can see sunspots, these dark, cooler areas of the surface
where magnetic fields are just going crazy.
And, of course, coronal mass ejections and flares.
You know, it almost looks like, to me, like volcanic eruptions, right?
But Joe said, unlike a volcano, there's more order to it because it's all controlled by the sun's electricity and magnetism.
So you see particles, you see what looks like plasma, this really, you know, bright stuff being blown off of the surface.
But then it follows these paths, beautiful paths across the surface where you see, you know, sinews, like these really like beautiful little traces of particles going across and lighting up.
Joe told me it's kind of like watching a pot of boiling water.
You've got this hot water that's constantly rising up to the surface and going back down
and churning around in the pot's convection zone, sometimes bursting out,
just like the plasma and magnetic fields do in the sun's convection zone.
Now, there's another NASA mission I have to mention.
It's called Parker Solar Probe.
We mentioned it at the top of this episode, and we'll talk about it a lot more,
a little later in this miniseries, because it's just so cool.
It's NASA's mission to touch the sun's corona.
And as it gets closer and closer to the Sun with every orbit,
it's starting to actually fly through these explosions.
Like, there was this one time where this huge coronal mass ejection hit the spacecraft,
and it was so powerful.
It rattled it. Like, you can actually see things move on it as it gets hit.
It almost looked like a bubble, you know, coming onto it, and then nothing.
And so, you know, you saw this big burst of gas go across the spacecraft,
and then the stars came out.
Because all of a sudden, the gas that was there, the atmosphere that was there, has been blown off and there's this huge vacuum behind it, which is just incredible.
So all of that to say, as you get closer and closer to the sun, it goes from being this beautiful, timid yellow ball of gas to being this very exciting, very powerful, very chaotic surface where something's always going on.
something's always happening.
And that activity is not always the same, right?
We've mentioned early on that the sun is near solar maximum right now in 2024.
So it's at its peak activity, and we're seeing more sunspots, coronal mass ejections, and flares than usual.
So I'm thinking if parts of the sun's atmosphere are exploding away and they're just getting blown off into space through coronal mass ejections, where do those go?
As those go out into space, you know, it's expanding.
into this sort of void between the sun and the earth.
And as it expands, there's not a lot of particles in between there,
but there's this constant sort of solar wind that's moving from the sun to the earth.
So we essentially live in that solar wind here on Earth, right?
Like in the atmosphere of our star?
I'm just thinking being in the crosshairs of a steady stream of particles from the sun
sounds not optimal.
Yeah, it can definitely be bad.
There's going to be a lot more of that to come later in this series.
But what you need to know right now is that here at NASA, we try to forecast and keep an eye on the sun's activity, because it can be hazardous.
Right. In really extreme cases, space weather can even affect us right here on Earth's surface.
In 1859, the most intense solar storm in history hit Earth.
It was called the Carrington event.
The sun released solar flare so bright that astronomers observed them from here on the ground for the first time ever.
When all that energy reached Earth, it set telegraph lines on fire.
And I'm thinking something like that would have to be way worse today, right?
I mean, in 1859, it's telegraph lines, but today we have way more electrical infrastructure.
And it would be in danger from that kind of event, right?
Yeah, I mean, there's the potential for things to be pretty bad.
But don't worry, luckily, we have this built-in shield that protects us from all but the worst storms here on Earth.
So as you move, as you get closer and closer to the Earth,
You come upon this obstacle, which is the Earth's magnetic field.
It's created by the rotation of the metallic core of the Earth that sets up this magnetosphere.
That's our protective shield.
You come up to that and all of a sudden you're blocked.
You as the solar wind are pushed off to the side or you're pushed off to the northern and southern regions of the Earth
and brought down into the poles where the field lines reconnect and then funnel particles down onto the Earth.
in those polar regions, which creates the aurora.
You can actually see visual evidence of our magnetosphere's protection at work.
If you're far enough north or south and catch a glimpse of the aurora, the northern and southern lights.
Particles, they come down, they hit the atmosphere on Earth.
And when they hit the atmosphere, the colors that you see in the aurora are the different composition of both the particles,
but also of the atmosphere lighting up as these particles hit.
Right now in 2024, the northern lights are going crazy up at the poles because the more radiation coming from the sun, the more particles our magnetic shield has to funnel down into the poles.
When the sun's activity is really high, you can actually even see the aurora further south.
The aurora, the northern lights, are just these beautiful displays in the sky, but beautiful displays of both the power of the sun, but also of our Earth's protective magnetosphere.
The protection is at work, right?
It's keeping those solar particles away from the surface of the Earth.
So, to recap, the sun makes life possible here on Earth through the light and heat it provides us.
But it also releases powerful storms and radiation that can disrupt our technology.
And so we have a quirk of planetary geology, our Earth's metal core, to thank for the shield that protects us.
That's pretty cool.
I still have one more question, though.
I mean, if the sun is sending out the solar wind in every direction, all this is.
time. I mean, only a tiny fraction of that is going to hit Earth, right? So what happens to the
rest of it? Well, as the solar wind expands out past Earth and through our solar system, it creates
this big protective bubble around us. We call that bubble the heliosphere. It keeps out most
of the galactic cosmic rays from elsewhere in the universe that otherwise would hit us on Earth
and damage our DNA. That bubble that the Sun creates, this protective bubble, is really one of the
things that has allowed humanity has allowed, you know, the habitability of the Earth to exist
because it's protected us from this, the harsh interstellar environment.
So I'm picturing those Russian nesting dolls, you know?
Like, we have a bubble here on Earth that protects us from the sun.
And then we're within this even larger bubble that the sun creates.
And that protects us from stuff coming from outside the solar system, right?
Exactly.
And if you're like me, you might be wondering how on Earth we know that.
Yeah, it's a good question.
We've studied the heliosphere in a lot of ways,
but one of the things we've done is actually send spacecraft out there,
like the famous Voyager missions that launched back in 1977.
Voyager 1 and 2 were the first NASA spacecraft to leave our solar system,
and the first to directly explore the heliosphere.
The Voyager missions, they have that golden record on them, right?
The mixtape of information about Earth and humanity,
that potential life and other parts of our own galaxy could maybe,
someday find.
Yeah, it's pretty wild to think about.
Near the beginning of the space age, we're sending this message in a bottle out into
the universe, expanding our horizons, way before all our modern sun-studying spacecraft.
...of two voyager spacecraft to extend man's senses farther into the solar system than ever before.
And decades later, it leaves the solar system and it detects the boundary of the heliosphere,
this bubble that has allowed humanity to flourish on Earth in the first place.
and that's given us this habitable planet that we can use to build spacecraft like the Voyager probes.
So the Voyagers moved out, and they punched out through the heliosphere in two locations,
roughly 100 times the distance between the sun and the Earth.
So at about 100 astronomical units is roughly where they punched out.
The most distant human-made object, NASA's Voyager 1 spacecraft,
is an interstellar space, the space between the stars.
Even though they're out in interstellar space now, the space between the stars, this wild west without the heliosphere's protection, they're still sending us back valuable data.
It was the first mission for us to really understand the interstellar medium.
It still had the instruments available.
It still had the observations available to punch out of our heliosphere and start to understand what that local interstellar medium is, what the gases between the stars are.
I'm still not over that distance, a hundred times the distance between the Sun and the Earth.
I mean, that's pretty far itself.
If you think about how we have Mercury and Venus between us and the Sun, what does the
heliosphere look like?
I mean, if it's a heliosphere, is it just a big sphere all the way around the solar system?
We still really don't know.
There have been other missions that have tried to detect its shape through remote sensing,
and there's another interstellar mapping probe planned.
But right now we just have theories.
And it's interesting to think about just like the structure.
What does our heliosphere really look like?
Okay, so there are basically two theories.
There's the banana slash croissant theory
that has to do with how the solar wind comes off the sun's poles,
which we still don't know about since we haven't really seen the sun's poles.
You know, these sort of theories say like maybe there's two jets
that go off the two poles and they wrap around
sort of making this banana or croissant shape kind of thing.
No, I like the banana slash croissant theory,
but there's series that say,
well, maybe it's just sort of a bubble
and it sort of terminates somewhere
a little farther back and things like that.
We really don't understand that at all.
We haven't sent a spacecraft down the tail of our heliosphere.
There are also other forces beyond our solar system
acting on the heliosphere,
kind of affecting its shape.
It's not all determined by the sun's activity.
Because if you think about, you know, how the sun has evolved
and how things have evolved over time,
you know, we're not the only star in the neighborhood.
And there's lots of stars and gas in the neighborhood
that affects how big that heliosphere is.
The bigger the heliosphere, so the more powerful the sun is,
the less radiation you get that comes in from outside.
The smaller it is, the more radiation you,
you get to come in from outside.
All of that other stuff, these clouds of interstellar gas,
change our heliosphere over time at the same time as our sun changes its activity on its
11-year cycle.
We've seen the heliosphere breathe.
It expands, right?
The solar wind is dynamic.
It changes how that interaction is.
It's a huge object.
Just a huge object.
So you need a star that's powerful enough to create a protective heliosphere, but not so strong that
It cooks you on your planet with radiation?
Exactly.
Our relationship to our nearest star is a lot more complex than you might think.
It's really both our nearest protective neighbor,
but also can be, I guess, a little bit of an honorary neighbor at times
and has these real explosive events
that can affect our critical infrastructure and things like that.
You know, you need the solar wind to create this protective bubble around the Earth,
but you also need the Earth's magnetosphere to protect us from that solar wind that's also protecting us.
It's sort of circular in that way.
It's like this beautiful balance.
It's a lot to think about because so much of our life depends on the sun being the stable partner that we have come to know throughout, you know,
not just our lives, but humanity's time on Earth.
But there's a lot of ways that that's not always the case, right?
It sounds like it's important to keep understanding how it all works.
Yeah, it really is, and it's all just a little mind-blowing to me.
But this is all just the start.
We're going to get into so much more in the coming episodes.
Okay, so what do we have to look forward to?
Can we get a little hint for now?
Yes, I will give you a hint.
A mysterious pink line in the sky called Steve.
Petroglyphs carved into a desert cliff a thousand years ago
that might help us understand our upcoming total solar eclipse in a new way.
And the story of a spacecraft lost spinning.
in space for months that, once it recovered, had an ability to discover new things close
to the sun that nobody expected.
The sun is just such a mysterious place full of new things to discover, but you don't have to
take my word for it.
Heliofysics is sort of at this really bright time in its path, right?
We're building upon the knowledge that we've gained about the sun, and we're really
turning it into a well-refined scientist.
topic about really something that's so fundamental in our lives, the sun, right?
Every day you wake up, see the sun, hopefully, depending on where you live.
And it's an amazing thing that we take for granted.
And it's so incredibly ingrained in what we do.
And it's a place where great discoveries are still to be made.
We'll have all that and more right here on Curious Universe.
And before we go, we have a special new segment for you.
What are you still curious about?
We ask that question to every single person we interview for this show,
and we want to know what you're curious about too.
In this segment, we'll take a question from a curious listener and track down the answer.
Today's question comes from Dallas Taylor.
He's a sound design and audio expert, and he's the host of the podcast 20,000 Hertz,
which explores the stories behind the world's most interesting and recognizable sounds.
Dallas, it's great to have you with us.
The feeling is mutual because I am so excited to talk to you.
You've produced quite a few episodes about space, right?
Yeah, so usually I do shows all about very recognizable sounds,
like the Netflix to Doom sound or the Wilhelm scream.
But we sometimes dabble in brain science and all sorts of things.
But what I spend a lot of my own free time on is just thinking about space and the unknown and all of that.
Let's hear a clip from one of those episodes.
Space Remix, which is all about what other planets might sound like.
Let's go from planet to planet in our solar system to find out what each surface would sound like to our ears.
Let's start closest to the sun.
Places like Mercury and these rocky bodies with no atmospheres would be similar to being in space.
There would not be much sound, if any.
Well, Mercury is an airless body, so we're back to listening for Mercury quakes, essentially.
that would be really the only source of sound.
And you could only hear these mercury quakes
if your head was pressed up against the rock
because there's no atmosphere for traditional sound to travel through.
Next up, Venus.
In my mind, what sound would be like on the surface,
because you have this really dense atmosphere,
much denser than Earths,
the sound would be more like or tend toward
what things sound like when you're underwater.
If you could imagine something in between air
in water, that kind of density. You're running your hand through that, and you would feel that.
One thing we do know about Venus is that it has lightning. So you might hear thunder.
I wonder what other things, like my voice might sound like. I'm on Venus in this ethereal world
that's a mix between a gas-like atmosphere and water. I'm almost floating, but yet it's not as
restrictive as being submerged in water. My voice, the thunder. It's all
slightly muffled and distorted as it travels through the thick atmosphere.
I recognize some of those voices, and it's cool that you feature NASA scientists in your show.
So, what are you still curious about when it comes to space?
So we went through every planet in the solar system, but we never talked about the sun.
And I have no idea what it would be like on the sun.
And it's more of a thought experiment, but I'd love to know if, you know, you know,
you know, if you don't immediately burn up, and if you're in some aspect of what you would call a surface, just let your mind go.
What would it sound like on the, you know, so-called surface of the sun?
Right. So another thought experiment, similar to what you did with the Venus there, we can do it with the sun and you're in luck.
Because in our last season of Curious Universe, we took a deep dive into that very question in an episode we called Hum of the Sun.
It turns out that we actually can listen to the Sun.
But it's a little complicated.
Our star is a really active place.
It emits this constant stream of particles called the solar wind.
And in that solar wind in space, plasma waves can travel, full of electric and magnetic fields.
You can't hear those waves in the same way you can hear sound waves in the air on Earth
because space just isn't dense enough.
But we can detect them with satellite instruments,
especially when they collide with Earth's magnetic field lines and vibrate them like
giant space guitar strings.
Then we can play those waves aloud here on Earth
and arrange our ears can hear.
But if we were actually standing on the surface,
would it just be like a loud roar?
Would it just be like,
so that's a great question.
And we have a whole division here at NASA
called Heliophysics that is focused on learning more about the sun
from space.
And one of the most exciting missions that's active now
is called the Parker Solar Probe.
One of the things that Parker Solar Probe
is going to do is touch the sun.
And so it's the man-made spacecraft that will get the closest to the sun that we've ever come.
So we'll be able to answer these questions with like real scientific data.
Oh, I love it.
Well, if you ever want to make any sound shows that are very romantic about space, you know who to turn to you.
It was great to talk to you, Dallas.
Great to talk to you too.
Thanks again to Dallas from 20,000 Hertz for his question.
Expect more answers to curious questions in the coming episodes.
This is NASA's Curious Universe.
This episode was written and produced by Christian Elliott.
Our executive producer is Katie Conants.
The Curious Universe team includes me, Jacob Penner,
Maddie Olson, Michaela Sosby, and of course, Patty Boyd.
Christopher Kim is our show artist.
Our theme song was composed by Matt Russo and Andrew Santaguita of System Sounds.
Special thanks to NASA's Heliophysics team.
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