Daniel and Kelly’s Extraordinary Universe - What was the brightest explosion ever seen?
Episode Date: August 15, 2024Daniel and Jorge look right into the beam of incredible astronomical explosions.See omnystudio.com/listener for privacy information....
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There's been a bombing at the TWA terminal.
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My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Wait a minute, Sam.
Maybe her boyfriend's just looking for extra credit.
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He doesn't think it's a problem, but I don't trust her.
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Hold up. Isn't that against school policy? That seems inappropriate.
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Hey, Jorge, you work with a lot of scientists.
Who is the brightest one you've ever interviewed?
Well, I have made a lot of Nobel Prize winners.
They're all pretty humble, but yeah, generally they're pretty sharp at that level.
You know, beams of light are shooting out of their eyes.
They have an aura of genius.
So do you think when you're talking to a scientist you can predict if they're going to be a future Nobel Prize winner?
If I could, that would be awesome.
I could probably make a lot of money that way.
Aren't there betting pools for Nobel Prize winners?
If there are, you probably qualify as insider information.
Well, good thing I'm not a betting person.
Hi, I'm Jorge McCartouettes and author of Oliver's Great Big Universe.
Hi, I'm Daniel. I'm a particle physicist, a professor at UC Irvine, and I actually do have a tiny slice of a Nobel Prize.
Ooh, what does that mean?
Like they shaved off a piece of the medal or something?
No, I'm one of a large group of collective winners of the Nobel Prize.
Oh.
Several years ago, they get the Nobel Peace Prize to the European Union.
And that's back when Britain was a member and I'm a citizen of the UK.
So I'm not sure if I lost it during Brexit, but I was briefly one 500 millionth of a Nobel Prize winner.
Oh, I see.
You and all Europeans have won the Nobel Prize.
well technically you're not part of Europe so yeah I think you did lose it
I used to round that up to one Nobel Prize now I guess I got to round it down to zero to zero
yeah well I think you could have rounded it down to zero before you know one 40th
million probably maybe count to zero well to me one 500 millionth was pretty different from
zero but I take your point but anyways welcome to our podcast Daniel and Jorge explained the universe
a production of iHeart Radio.
In which we think everybody deserves a prize
for their curiosity about the universe.
We're here to stimulate that curiosity,
to encourage it,
and to go with you on the journey of exploration
of understanding the universe.
We think we hope we believe
that the universe out there
can be understood
and deserves to be understood
and that everything that scientists have figured out so far
and that they're puzzling over currently
deserves to be explained to you.
That's right.
We're here to illuminate the dark,
darkest corners of science and take you on a trip to the bright future of our understanding of how things work and why things are the way they are.
We want to understand everything here on Earth, how water flows, how mountains form, the history of life.
But we also want to understand our vast cosmos. What's happening in the dark, deep reaches of space?
How did the universe get to look the way that it does?
What are the most powerful forces operating on galaxies and stars and galactic clusters out there?
shaping the entire structure of space time and the universe.
And to do that, we have to look out into the night sky
and gather messages that are coming here from the rest of the universe.
Yeah, because the cosmos is vast and mostly dark
with lots of empty space,
but there are some bright spots out there,
making the universe visible to us
and giving us information about what's out there
in the farthest reaches of existence.
Though very few humans have actually left the surface of the earth
for significant periods of time,
and entered even our space neighborhood,
we have a pretty good understanding
of what's going on in the rest of our galaxy,
the structure of galaxies beyond that,
and all of that comes from gathering that information
that's beamed to us from the rest of the universe.
Imagine if instead the universe was totally dark.
We would have no idea what was out there.
We're grateful that at least some little fraction of it
is shining brightly and letting us know what it's up to.
Yeah, there are things happening all over the universe,
creating light, blasting it out into the universe.
But some of them are maybe a little bit stronger than others.
That's right.
We have a whole series of episodes about the darkest things in the universe,
dark matter and the mysteries of the missing gravity.
But today in the podcast, we're going to go in exactly the opposite direction.
So today on the podcast, we'll be tackling the question.
What was the brightest explosion ever seen?
And was it that moment when Jorge finally understood particle physics, boom, mind-blown.
As that happened?
I'm anticipating it, man.
We're building up to it.
Has that even happened for you?
You know, there's that old quote.
If you think you understand quantum field theory, then you don't understand quantum field theory.
So it's a matter of degrees, I think.
Yeah, yeah.
It's a dimmer setting, the light bulb of quantum physics.
But yeah, there are explosions happening all over the universe, and some of them are incredibly
bright and some of them are less bright, but maybe we haven't seen all of them. Maybe there
are some that we have managed to see out there. Something that's wonderful about exploring the
universe is being shocked by the scale of it. Learning how deep the history of time is, not thousands
of years, not millions of years, but billions of years. Learning how large the universe is,
how many billions of light years across stuff has spread out. These enormous scales that
shock our understanding also serve to give us a better context for our existence. Turns out the
Earth and the Milky Way are a tiny little speck of dust in the vast cosmos. But there are other
dimensions to be shocked in. The sun you think is quite bright. It turns out the universe gets
much, much, much brighter than that. Yeah, the universe never ceases to make us all feel tiny and
insignificant and short-lived compared to the scale of the cosmos and its existence. But as he said,
there are things that maybe would even shock a physicist about how bright they are.
Absolutely.
And today we're going to be learning about the brightest of all time, what physicists
called the boat.
The boat?
B-O-A-T.
The biggest of all time?
The brightest of all time.
Not the banana east of all time.
The brightest of all time.
The amazing of all time.
So as usual, we were wondering how many people out there had thought about this question,
about what is the brightest explosion ever seen in the universe?
So Daniel went out there as usual to ask people this question.
Thanks very much to everybody who plays for this segment of the podcast.
And if you'd like to hear your voice for future episodes, please don't be shy.
We would love to add you to our group.
Write to me to questions at danielanhorpe.com to volunteer or send me questions or send me ideas
or pictures of your cats, whatever we love to hear from listeners.
And today, Daniel, what are our players playing for?
They're playing for the recognition of having their voice on the podcast.
Their friends and relatives will all be jealous.
They'll be brightly jealous.
They're playing for the biggest banana of all time.
So think about it for a second.
What do you think is the brightest explosion ever seen?
Here's what people had to say.
I am going to say that is a supernova explosion.
either that or the source of whatever gamma ray bursts are.
The biggest explosion ever seen would have to be the Big Bang.
Although there was nobody around to see it,
we can still see the cosmic microwave background radiation.
So we still can see it.
But that's not really bright anymore.
So I don't know, you got me in a quandary here.
So it's probably a supernova.
I would imagine the Big Bang was pretty bright, and then maybe gamma-ray bursts, but maybe something to do with merging black holes or merging neutron stars.
I guess bright doesn't necessarily have to be in our visible spectrum.
All right.
A couple of answers.
Kind of trick answers here.
The Big Bang was maybe the biggest explosion.
You can't argue with that.
You can't actually argue with that.
I don't think of the Big Bang as an explosion.
I think of it as an expansion.
Oh, I see.
You're going to use grammar to disqualify their answer.
I know.
Words, meanings, words having meanings.
Oh, so annoying.
I know.
It should just all be bad, right?
But, I mean, you do call it the Big Bang.
I mean, yourself are saying it's a bang.
Well, you know, there's that famous story about how the Big Bang was not named by anybody who actually believed in the Big Bang, but by proponents of the steady state theory.
Mm-hmm. But it's physicists still call it the Big Bang, right?
They do still call it the Big Bang. Yes, absolutely.
They don't call it the Big Stretch or the Big Expansion.
I think we should call it the Big Stretch. I think that's a much better name.
Yeah, absolutely.
Maybe we should amend the title of this episode to what was the biggest explosion besides the Big Bang?
The brightest explosion, though. Yeah, good question.
I'm not sure how you measure the brightness of the Big Bang.
Now, the way we phrased this question, what was the brightest explosion ever seen?
Are we only counting the ones that we've seen or that we think happen?
Or is that the same?
Well, we're only going to talk about the ones that we've seen.
But as soon as you've seen something extraordinarily bright,
it means that there's something out there capable of making very, very bright explosions.
And it's very unlikely you've seen the brightest one.
So it's like discovering a unicorn, you figure,
ooh, there are probably other unicorns in the forest,
maybe even with longer horns.
So we could only talk about the brightest one we've seen.
That suggests that there are very likely even brighter explosions out there we haven't seen.
But that's an assumption, right?
I mean, there could just be one unicorn out there in the universe.
Oh, absolutely.
It's a statistical statement.
But yes, as soon as you discover one unicorn, you figure like, well, probably you had parents.
Maybe it had siblings.
You know, there probably other unicorns out there.
But it could be the sole unicorn, you know, created by a random collection of quantum fluctuations.
that's also a possibility, even if it's unlikely.
It could be the unicorn of unicorn spotting.
Yeah, we could tell it for a billion dollars.
That should be our startup.
My startup idea is give me a billion dollars.
I will make you a unicorn.
And then it'll be a unicorn startup.
You would only make one unicorn.
Otherwise, it's not worth much.
Yeah, but if you only have one, you can set the price, right?
I mean, I'm not an economist, but.
Yeah, I think that's how economy worry.
Sure.
Maybe that's our problem.
We're selling shit.
chairs and our unicorns,
folks. Unicorns, singular.
But anyways, it's an interesting question.
Well, what's the brightest explosion ever seen?
And so, Daniel, that step us through.
What are some things that can cause explosions in the universe?
Well, first, I think it's useful to think about brightness.
Like, what do we mean by brightness?
Obviously, you're very bright.
All of our listeners are very bright.
Our children are very bright.
But when we talk about brightness in an astronomical setting,
what we mean is like how many photons are arriving from it
to Earth.
And it used to be that astronomy only really dealt with photons.
We had telescopes that could see photons.
We used our eyeballs.
These days, though, we have other devices like particle detectors and gravitational
wave detectors that can see other kinds of messengers from astronomical events.
Now, would brightness and photons be the best way to, you know, measure the energy of an
explosion?
Like, could there be an explosion that maybe, you know, throws out other kinds of particles?
more than photons or neutrinos or something like that
that might have more energy but be less bright
or is like a pretty good indication of the energy?
No, different astronomical events have a different fraction
their energy produced in photons and neutrinos
or in gravitational waves.
So the best way to do astronomy,
they call these days multi-messenger astronomy
where you're looking for photons
and you're looking for particles
and you're looking for gravitational waves.
It's the best way to get a handle on what happened.
For example, when we look at neutron star collisions,
You can sometimes see a gravitational wave and also see light from the collision.
But sometimes, like supernova, can release huge amounts of energy just in neutrinos.
Because when the neutrinos are produced in the supernova, they're not reabsorbed.
They just fly right out.
Because the supernova itself, though it's super dense, is also transparent to those neutrinos.
Whereas photons get reabsorbed.
So definitely there are things that are brighter in neutrinos than in photons.
So that makes it very, very complicated.
I think today let's just focus on the photons.
Okay, let's just focus on the photons
because my eyeballs can't see neutrinos yet.
You'd have to have eyeballs the size of swimming pools.
Oh, Daniel, that's very flattering.
Thank you.
You're saying my eyes are endless pools of...
Of chlorinated water, yeah.
Of physics detection technology, yes.
You're like an anime character with big eyes, yeah.
Yeah, there you go.
And the other issue with brightness is that it depends a little bit
on where you are.
Like you could have a really bright source,
but it's really, really far away.
And so it appears quite dim.
Like when quasars were first discovered,
they were quite bright in the sky.
And then we discovered, oh my gosh,
they're also super duper far away,
which means at their source,
they're extraordinarily bright.
So what astronomers typically do is define brightness
by how bright something would seem
if you were one AU away from it.
If you were like the distance the Earth is from the sun
away from that object, how bright would it be?
That's what an AU is, right?
It's like an Earth distance from the sun.
Yeah, exactly.
All right.
So step us through like how bright are things in the night sky?
Yeah.
So if you define the sun as brightness of one, then you can look at things like some of the biggest stars that are out there.
Like the biggest brightest star ever discovered.
It's 315 solar masses.
It's got the amazing name of R136A1.
And it's 8.3 million times brighter than the sun.
Like, if you took that star...
What?
Yeah, you took that star and put it in our solar system and looked up at the sky, it would be 8.3 million times as intense as the sun.
Wow, you would need 8.3 layers of sunblock just to walk out into the sun.
8.3 million, yes.
8.3 million, yes.
Exactly.
So that's the brightest star in the universe.
And already that gives you a sense that, like, wow, the stuff in our neighborhood, not really that bright.
when we're talking about like Hall of Fame brightness.
Wouldn't this star be huge or is it still a small star?
No, it's very large.
It's right up on the edge of the biggest star you could have, around 315 solar masses.
Because bigger stars have a higher temperature at their core, so they burn hotter and faster.
They don't last very long, typically.
And they also produce an enormous amount of radiation, which pulls the star apart.
Stars are actually a delicate balance between the radiation pressure from fusion.
and the gravitational pressure inwards from all of that mass.
So it's sort of incredible that so many stars are stable for millions and billions of years.
These guys essentially tear themselves apart.
Anything bigger than that can't really last very long.
So this is the brightest star ever seen.
Could you even stand at one AU away from the star?
Would you be inside the star?
You wouldn't be inside the actual edge of the star.
Its radius is like 43 times the radius of the sun.
So it's much, much denser than our sun.
But it's nowhere near an AU, for example.
And why is it brighter?
Is it just more dense?
So there's more fusion going on?
Yeah, fusion is very nonlinear.
And so because you have so much more mass and it's more dense, then it's much hotter.
The pressure and temperature at the core is much greater.
And remember that while there's fusion happening at the core of our star, it's still pretty inefficient.
Like most of the hydrogen in the star is not fusing because fusion's a hard thing to make happen.
You've got these two protons.
You're trying to squeeze them together.
Their electromagnetic forces are trying to push them apart.
Most of the time in the sun, protons don't fuse.
But the higher the temperature and the higher the pressure, the more often you do get fusion happening.
And so the fusion is just much more efficient at the heart of this star, which heats the whole thing up and makes it brighter.
Whoa.
But you said that they don't last very long.
Yeah, these stars last for like millions of years, whereas smaller stars like ours last billions.
and red dwarfs can last even longer, maybe even up to trillions of years.
We're not sure because the universe is kind of young
compared to the expected lifetime of some of these stars.
Now, is that as bright as it gets out there in space?
That's not even close to how bright things get.
That's the brightest star we've seen,
but stars are not bright compared to like the radiation emission
at the heart of galaxies.
Big galaxies have big black holes at their centers,
and their enormous gravity creates a lot of high temperature
and high pressure in the accretion disk around the black hole.
So the black hole, of course, is black.
Maybe there's hawking radiation, but that would be very, very dim.
But because it has so much gravitational energy,
there's a big, swirling mass of stuff around the black hole,
and that is so hot it's emitting a lot of radiation.
That radiation then gets guided by the magnetic field of the black hole up and down the poles.
Sort of the same way that, like, the Aurora Borealis, guides charged particles to the north
pole and the south pole. Here, the magnetic field of the quasar creates two beams of particles
when shooting up the north pole and one shooting down the south pole. And that's what a quasar is.
That's also called an active galactic nucleus. Wow. So it creates a jet of particles or light?
Or both? If you look at pictures of galaxies with jets, these jets can be enormous. They can be
even much longer than the galaxy itself. The power of the hearts of these galaxies is really
incredible. And there's an enormous amount of photons also emitted here because this is just
like hot particles and hot particles emit photons. Because I guess it can't guide the photons
through the North Pole and South Pole, but it guides other particles and then those particles
are what emit the brightness, the light. Yeah, exactly. And anytime you have charged particles
changing direction like an electron flies through a magnetic field and bends, how does it bend? It has to
bend by emitting a photon. So you have accelerating charged particles. You're going to get lots and lots
of photons. Like in the particle colliders, like the large Hedron Collider or the large electron
positron Collider, one of the biggest challenges is that these particles are bending with magnets
and constantly losing energy to radiation. And so that's why you get so many photons.
All right. I have more questions about this quasar and about maybe what could be even brighter
than a quasar. So let's set the dimmer to high on those questions. But first, let's take a quick break.
December 29th, 1975, LaGuardia Airport.
The holiday rush, parents hauling luggage, kids gripping their new Christmas toys.
Then, at 6.33 p.m., everything changed.
There's been a bombing at the TWA terminal.
Apparently, the explosion actually impelled metal, glass.
The injured were being loaded into air.
Ambulance is just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, and it was here to stay.
Terrorism.
Law and Order Criminal Justice System is back.
In Season 2, we're turning our focus to a threat that hides in plain sight.
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Listen to the new season of Law and Order Criminal Justice System on the IHeart Radio app, Apple
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My boyfriend's professor is way too friendly and now I'm seriously suspicious.
Wait a minute, Sam, maybe her boyfriend's just looking for extra credit.
Well, Dakota, it's back to school week on the OK Storytime podcast, so we'll find out soon.
This person writes, my boyfriend has been hanging out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now he's insisting we get to know each other, but I just want her gone.
Now hold up.
Isn't that against school policy?
sounds totally inappropriate. Well, according to this person, this is her boyfriend's
former professor and they're the same age. It's even more likely that they're cheating.
He insists there's nothing between them. I mean, do you believe him? Well, he's certainly
trying to get this person to believe him because he now wants them both to meet. So, do we
find out if this person's boyfriend really cheated with his professor or not? To hear the
explosive finale, listen to the OK Storytime podcast on the IHeart Radio app, Apple Podcasts, or
wherever you get your podcast. I'm Dr. Joy Harden-Brandford. And in session 421, if they're
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Because I think hair is a complex language system, right?
In terms of it can tell how old you are, your marital status, where you're from, you're a spiritual
belief.
But I think with social media, there's like a hyper fixation and observation of our hair, right?
That this is sometimes the first thing someone sees when we make a post or a reel is how our hair
We talk about the important role
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and how breaking up with perfection can actually free us.
Plus, if you're someone who gets anxious about flying,
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It's easy. It's easy to just drink the extra beer. It's easy to ignore, to suppress, seeing
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Listen to the psychology podcast on the iHeartRadio app, Apple Podcasts, or wherever you get your
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We're talking about the brightest explosion ever seen.
And then you were saying a quasar has many times more brightness than.
and the brightest star that we know about.
Yeah, quasars in the sky are like bafflingly bright.
It was a huge mystery for a long time
before we even knew that there were black holes
at the hearts of galaxies.
People saw these sources in the sky
and they calculated the distance
and then they were like, oh my gosh,
it's already bright in the sky
and it's super duper far away
because quasars tend to be formed
in the early universe and not recently.
So all the quasars we see
are like really far across the universe.
And so you do that calculation,
you discover that like, wow, quasars are trillions of times brighter than the sun.
Trillions.
Trillions.
Yeah.
There's one called 3C273.
It's the brightest quasar we know officially.
And it's four trillion times brighter than the sun.
Like if you were one AU away from it, it would be equivalent to having four trillion suns.
But only if you're at one AU at the north or south poles, right?
Yes, exactly.
If you're at the horizontal or you're a little bit tilted away from it, then it's less bright.
Now, does that technically count as an explosion, though?
I don't think it counts as an explosion because it's constant, but it is super duper bright.
And it's super directed too, right?
Like you just said, it's not like it's not an explosion going in all directions.
It's like more like a laser.
Yeah, it's more like a laser, like a pencil beam, which is actually really useful.
And we can use these quasars, not just to understand the early universe, but also to understand
what's between us and the quasars.
There's lots of studies where people examine the light from quasars and they use it as a probe
all the material between us and the quasar.
For example, the dark matter density and the gravitational lensing that happens along the way.
They're really useful.
Sometimes a quasar can get even brighter due to relativistic effects.
These quasars are called blazars.
If the quasar is moving towards us, then its light is enhanced by relativistic effects and
it can seem even brighter than a quasar.
Wait, a blazar is a quasar that's moving towards us.
It's not just a quasar with a nice jacket on.
Is that what you mean?
Like it's a quasar moving towards us?
Well, a blazar is a quasar.
It doesn't have to be just moving towards us, but it's pointed like directly at the earth.
We can see these quasars, even if they're not directly at us, because we can see their jets and the light emitted.
But if they are actually pointed directly at us, then we call them a blazar.
Wait, that's the only difference?
Is that it's pointing at us?
Mm-hmm.
Yeah.
Blazars are quasars that are basically pointing right at the earth.
And you need a whole new name for that.
Well, you know, it's historical.
People see these things in the sky.
They don't always understand the connections between them.
It's like, why do we even have constellations?
You could say, hey, now we know that like stars and constellations, some of them are super
close and some of them are across the galaxy.
Why do we group them together?
It's historical, you know?
People have called that Ursa Minor for a long time, so we're going to keep doing it.
So Blazar then is a quasar that's pointing at us.
Now, is it brighter than four trillion times brighter than the sun?
Yeah, the brightest blazar is 300 trillion times.
brighter than the sun so we're talking about a factor of a hundred boost when a
quasar is pointed right at us so this is if we are one a u at the north and south
pole of a quasar it's 300 trillion times more than brighter than the sun
but if we're not in the north and south pole you're saying it's more like four
trillion times yeah exactly and so not recommended to do any sunbathing on the north
or south pole of a blazar unless you have 300 trillion layers of sunblock also known as
like three light years of lead still might not be enough now that sounds pretty intense but if we're
counting beams i wonder like is it brighter than the brightest laser we've made here on earth
it's much brighter than the brightest laser yes i mean if you were one a u from the brightest
laser you would not think it's very bright even a laser is pretty collimated it's going to spread out
and an a u is a large distance but in terms of intensity per you know area is it as intense or more
intense?
These blazers are much more intense than any source on Earth at one AU, yes.
But these are constant things, right?
Blazars keep pumping out.
So I don't know if it really counts as explosions.
And the brightest thing in the universe is actually not something that's constant.
So then we aren't disqualifying quasars and blazers from being the boats.
We don't even need to disqualify them.
They don't even qualify.
We're seeking their chances of being the boat.
Yeah, we're going to torpedo them.
But even if we didn't, they still wouldn't qualify because the brightest thing in the universe is an explosion and it's also much brighter than the most constant thing in the universe, which are blazars.
Well, all right.
What are these things that are brighter than a blazer?
Is it a dinner jacket, R?
I don't know if it's white tie or black tie, right, which is brighter, right?
It's a glittery disco jacket.
Ooh, sparkle tie, yeah.
The brightest explosion in the universe and also the brightest.
thing we've ever seen is a gamma ray burst. These are sort of mysterious and enormous bursts of
gamma rays. Gamma rays are just very high energy photons that we see sometimes in the night sky.
Meaning like we have gamma ray antenna and gamma rays are just a kind of light, right? Like it's a high
frequency light? Yeah. Gamma rays are very, very high energy. You know, photons exist all across
the electromagnetic spectrum. Some of them we call in the visible range. Some are very long wavelength
in the infrared or radio waves.
But these are just artificial divisions.
Above the visible, we have ultraviolet and then x-rays and then gamma rays.
But again, these are just like historic dotted lines we've put on the electromagnetic spectrum.
There's nothing above gamma rays.
So gamma rays include everything above x-rays and then out to infinite energy.
Whoa.
So we have these antennas out there on Earth that can detect gamma rays.
And sometimes we get these bursts coming from space, like these huge kind of waves of gamma rays.
Yeah, exactly.
And it's fascinating history because this is something that really benefits from the Cold War.
Like in the second half of last century, the United States military was really curious whether the Soviet Union was doing atmospheric nuclear testing.
This is before it was ruled out.
So they built satellites and all sorts of technology to try to detect nuclear testing.
And sure, they found some, I guess, but they also spotted these weird bursts in the sky of gamma rays that they didn't understand.
they were not coming from below.
They were coming from above.
That's how gamma ray bursts were first discovered.
I love when we spend money on the military,
we accidentally end up doing science.
Are you making a case for more military spending?
I don't think military spending is a very efficient way to do science.
I'm just grateful when sometimes that money turns out to be useful for science as well.
I see. It's a win. It's a win for everyone.
Yeah, I'll take it.
I mean, the military budget totally dwarfs the science.
budget, but anyway, that's a topic for another time.
How bright are these gamma-reberths?
Some of them are crazy, crazy bright.
Like, we've seen gamma-ray bursts that are a million trillion times brighter than the sun,
like a quadrillion times brighter than the sun.
It's a little hard.
Yeah.
In terms of how bright we think they are at the source.
Here on Earth, we don't get a million trillion times more gamma rays than the sun.
Yes, that's right.
We were all killed several years ago due to gamma-ray burst.
We're just now catching up.
No, this is at the source.
Absolutely.
Fortunately for us, they're quite distant.
So when they get here on Earth, there's a few very high energy gamma rays, but we're not all fried.
And how do we know how far they are?
Like, we're just getting a blip on our antennas.
Like, how do we know, like, how far away they came from?
Yeah, it's a good question.
We're not exactly sure.
Because for many of them, you look in the night sky where they came from and there's, like, nothing there.
It's not like you can point to and say, oh, it came from this star that went supernova.
or it came from that galaxy.
Like, you look at the sky.
You're like, oh, here's a huge source of gamma rays.
There's nothing in that sky there that we can see.
It must mean that there's something extraordinarily distant.
So there's a lot of uncertainty on the inherent brightness of these things.
A huge amount of uncertainty, right?
Like it could be something close that's dim or it be something really far that's super duper bright.
How do you tell the difference?
Well, it's definitely not something close and dim, right?
If it was something close, we would see it because these things are very, very bright.
It could be something close that's dim.
most of the time and occasionally bright.
But yet there is uncertainty on the distance to these things.
Meaning like the range goes from 60 watt to a million trillion times brighter than the sun.
Yeah, we don't know exactly how far they are.
All of the gamma ray bursts that we've seen have originated from outside the Milky Way galaxy,
which means that they're very far away.
But there's a huge range there, right?
They could be a neighboring galaxy.
They could be a very, very distant galaxy at the edge of the universe.
And we think they came from outside the Milky Way because when,
When we pinpoint where they came from, we don't see anything that we think is in the Milky Way.
Yeah, exactly.
And we think these things are extraordinarily bright.
And any gamma ray burst in the Milky Way that's actually pointed towards Earth would probably fry the Earth.
And there are some theories about how, like, some mass extinctions might have occurred due to gamma ray bursts in the Milky Way, for example.
But yeah, these things we think are extraordinarily bright.
I mean, it's hard to get your mind around these numbers.
It's easier if you express it like in terms of how much energy the sun puts out.
So, for example, our sun in its entire lifetime will put out as much energy as is in one of these gamma ray bursts for one second.
So like a second of gamma ray burst is 10 billion years of the sun.
We think.
Yeah, we think.
There is definitely a lot of uncertainty here.
I mean, it sounds like a huge amount of uncertainty, right?
How do we know how far away it is?
Yeah, we don't know.
We can set sort of like lower limits because we know the nearest neighborhood and we can tell that there's nothing there that's generating these things.
you know there's a lot of fuzziness and some general arguments there
but yet take these numbers definitely with a big grain of salt
and you said it was a mystery for a long time meaning
that we still don't know what makes these bursts
we still don't really understand it yeah we have some theories
it turns out the gamma ray bursts come in two categories
is like shorter ones and longer ones
the shorter ones last for like seconds or tens of seconds
and the longer ones last for like minutes
so that seems like probably there are two different things going on
there. And there are theories. The leading theory is that short gamma ray bursts might come from
merging neutron stars like we talked about. You know, neutron stars are these very dense objects
that the end of life of large stars, not so big that they become a black hole, not so small,
they become a white dwarf, but having enough mass to become very dense neutron stars. And often
these stars are in binary systems. And then at the end of their life, they're orbiting and
eventually collapse and fall into each other. And these are incredibly powerful events.
generate gravitational waves, they generate the conditions needed to make like gold and platinum
and all the heavy nuclei in the universe, just like supernova, and also generate very high energy
gamma rays.
Would they also generate regular light, like visible light, or would they maybe only generate
gamma rays?
And that's why we don't see them with the naked eye.
Yeah, we definitely see neutron star collisions, and we've seen some.
We've also correlated some with gravitational waves.
But, you know, there's lots of different varieties of these things, different masses of neutron stars, and the collision themselves can happen in lots of different ways.
So we've seen neutron star collisions that haven't caused huge gamma ray bursts, but there's a speculation that sometimes neutron star might cause these incredibly bright gamma ray bursts.
But it's not something we understand very well.
Even the heart of a single neutron star is not something we understand.
Like, what is the state of matter under these incredible densities?
Is it a quark gluon plasma?
Is it some other state of matter?
Is it nuclear pasta?
We have a whole episode about this question.
We're really just the very beginning of the ability
to think about these things coherently.
And then take two neutron stars
that are swirling around each other
and the dynamics of that and the relativity.
It's really just sort of beyond our ability
to calculate in a robust manner.
And so there's a lot of sort of theoretical questions
about whether those even could cause gamma ray bursts.
Meaning they might not even be bright enough
or they might not be enough to generate the kinds of bursts we think we're seeing.
Yeah, it's the leading theory, but it's definitely far from proven.
All right, let's dig in more into what could be causing these gamma-ray birds,
and then we'll get to the boat, the brightest of all time.
But first, let's take another quick break.
The holiday rush, parents hauling luggage, kids gripping their new Christmas toys.
Then, at 6.33 p.m., everything changed.
There's been a bombing at the TWA terminal.
Apparently, the explosion actually impelled metal glass.
The injured were being loaded into ambulances.
Just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, and it was here to stay.
terrorism law and order criminal justice system is back in season two we're turning our focus to
a threat that hides in plain sight that's harder to predict and even harder to stop listen to the
new season of law and order criminal justice system on the iHeart radio app apple podcasts or
wherever you get your podcasts my boyfriends professor is way too friendly and now i'm
seriously suspicious. Oh, wait a minute, Sam. Maybe her boyfriend's just looking for extra credit.
Well, Dakota, it's back to school week on the OK Storytime podcast, so we'll find out soon.
This person writes, my boyfriend has been hanging out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her. Now, he's insisting we get to know each other,
but I just want her gone. Now, hold up. Isn't that against school policy? That sounds totally
inappropriate. Well, according to this person, this is her boyfriend's former professor,
and they're the same age. And it's even more likely that they're cheating. He insists there's
nothing between them. I mean, do you believe him? Well, he's certainly trying to get this
person to believe him because he now wants them both to meet. So, do we find out if this person's
boyfriend really cheated with his professor or not? To hear the explosive finale, listen to
the OK Storytime podcast on the IHeart Radio app, Apple Podcasts, or wherever you get your podcast.
I'm Dr. Joy Harden Bradford. And in session 421 of therapy for black girls, I sit down with
Dr. Othia and Billy Shaka to explore how our hair connects to our identity, mental health, and the
ways we heal.
Because I think hair is a complex language system, right?
In terms of it can tell how old you are, your marital status, where you're from,
you're a spiritual belief.
But I think with social media, there's like a hyperfixation and observation of our hair, right?
That this is sometimes the first thing someone sees when we make a post or a reel is how our hair is styled.
We talk about the important role hairstylists play in our community,
the pressure to always look put together,
and how breaking up with perfection can actually free us.
Plus, if you're someone who gets anxious about flying,
don't miss Session 418 with Dr. Angela Neil Barnett,
where we dive into managing flight anxiety.
Listen to Therapy for Black Girls on the IHeart Radio app,
Apple Podcasts, or wherever you get your podcast.
I'm Dr. Scott Barry Kaufman, host of the Psychology Podcast.
Here's a clip from an upcoming conversation about exploring human potential.
I was going to schools to try to teach kids these skills and I get eye rolling from teachers or I get students who would be like it's easier to punch someone in the face.
When you think about emotion regulation, like you're not going to choose an adaptive strategy which is more effortful to use unless you think there's a good outcome as a result of it if it's going to be beneficial to you.
Because it's easy to say like go you go blank yourself, right?
It's easy.
It's easy to just drink the extra beer.
It's easy to ignore to suppress seeing a colleague who's bother me.
you and just like walk the other way avoidance is easier ignoring is easier denial is easier drinking
is easier yelling screaming is easy complex problem solving meditating you know takes effort
listen to the psychology podcast on the iHeart radio app apple podcasts or wherever you get your
podcasts all right we're
We're hopping on a boat here, Daniel, trying to find the brightest of all time.
The brightest explosion of all time, right?
Yes, exactly.
It's the biggest exploding boat.
Yeah, and it's really wonderful.
I love the experience of just being overwhelmed by stuff that happens in the universe,
really stretches your minds, even try to conceive of these incredible events.
You know, it makes everything that happens here on Earth just seem inconsequential.
Yeah, I mean, for it to have been so bright.
that even though it's super duper, duper far away,
we're still seeing it here on Earth.
It's pretty amazing, right?
I'm sure the rest of the universe is also seeing it.
Yeah, exactly.
And unless this is the unicorn of unicorns,
it means there's probably even brighter stuff out there
that we're missing.
Oh, maybe it is a unicorn making this.
Yeah, how are we?
Maybe it's the collision of two unicorns
when they cross their horns.
Maybe that's what happens.
Yeah, yeah, or maybe it's a unicorn farting.
Let's keep it clean for the families out there.
Yeah, it's nothing wrong with farts.
Everybody farts.
Even unicorns.
This is not a fart podcast, folks.
We're talking about bright explosions, not stinky ones.
But you did say these things are really far away.
They are mind-blowingly far away.
Exactly.
So we have the short gamma-ray bursts that are probably merging neutron stars.
And then we have these longer gamma-ray bursts,
which just means that we see photons for longer,
like it lasts for minutes.
instead of seconds.
And the leading theory here is supernova collapse, that when supernova collapse, sometimes
they create these very bright bursts of photons.
Not always.
Like we see supernovas that don't cause gamma ray bursts, but sometimes we think like there's
a jet of matter ejected from the supernova, like the collapse isn't completely symmetric.
And this jet of matter, sort of like a blazar or a quasar, can accelerate particles and generate
enormous bursts of very, very intense light.
Does that mean we have to disqualify supernova from our category here?
Because a burst is not sort of going in all directions?
No, I think it's fine.
I don't think there's a reason to disqualify it just because it's focused.
You know, I think it's still, it's a bright and it's an explosion.
So, yeah, I think it qualifies as one of the brightest explosions.
It's more of a float, like the focused,
a focused, focusedly bright of all time.
All right, so those are leading theories, but we're not sure.
it seems. You're saying maybe even a supernova emerging neutron stars might not be
powerful enough to generate the kinds of gamma ray bursts we're seeing. Yeah, exactly. And
this is the exciting edge of astronomy. When we see stuff in the night sky, we can't quite
explain. We're not sure if it's like a weird extreme version of something we've already seen
or if it's something totally new, a kind of thing out there in the universe we've never
considered. And that's definitely happened, right? Think about the first time we discovered
supernova or black holes or quasars all these things were discoveries of something new out there in the
universe a whole new category of thing the universe can do so we don't really know if gamma ray burst
represent that or if they represent like the extreme edge of some kind of thing we're familiar with
yeah it's pretty exciting so is that then the brightest thing we've seen explode out there in the
universe so the brightest thing we've ever seen in the universe is a gamma ray burst and it's one that just
happened last year like the record was set in october 2023 oh was there a celebration was the
guinness world record official there at the telescope um i think that everybody was too stunned
like this is something just crazy bright brighter than anything we've ever seen by like a big
factor this is a hundred times brighter than any other gamma ray burst we've ever seen which remember
is already like quadrillions of times brighter than the sun.
Wow.
That's incredible.
But then do we know how far away this one was?
Like maybe it was dimmer than the ones before.
It was just closer.
They think this one might just be closer.
They actually have a candidate to where it might have come from,
which is a galaxy only two and a half billion light years from Earth.
And so it might be why it seemed brighter here.
And it seemed like the jet might be like pointed right at us.
That's sort of one theory.
for why this one was so bright.
But you know, we have this telescope orbiting Earth.
It's called the Fermilat,
and it's excellent at finding gamma rays,
really high energy photons.
It's kind of like a particle detector in space,
so I think it's pretty cool.
Like photons enter the telescope,
and it's not like a telescope like Hubble,
where you have lenses and optics.
Instead, it converts a photon into electron and positron,
then it tracks those particles.
So sort of like a very high energy particle detector.
And this thing was totally overwhelmed,
like it was just flooded with higher energy photons than it had ever seen before.
Wow, like it maxed out the sensor.
Yes, exactly.
It saturated that eyeball in space.
It was totally overwhelmed.
And not just our sensors, like the ionosphere, this part of the atmosphere of the earth,
the whole thing swelled up for several hours.
This is the kind of thing that happens when, like, we get a big solar flare,
like when the sun burps out an enormous number of particles towards the earth at the ionosphere responds.
But this is something that happened like billions of light years away
and it still made the earth like a little swollen and inflamed.
Wow.
Now, how do we know where it came from?
We don't know exactly, but there's sort of a candidate galaxy in that direction.
So people think maybe it came from there.
But, you know, this is all very speculative.
You can't really tell.
I mean, like, how do we triangulate where it came from?
Oh, we can measure the direction of these photons.
Like Fermilat is a detector.
And so we can see the trajectory of the particles that come from the photon.
so we can reconstruct the direction of these photons.
What do you mean we can see the direction?
How do we do that?
Well, the photon turns into an electron and positron pair,
and those carry the momentum of the original photon.
And then we have layers of detector.
So we have like 10 or 100 layers that detect the motion of the particles that come from the photon.
And then we can reconstruct that track,
and it points back to where it came from.
Oh, I see.
It's sort of like a cake.
You know, like if you stick your finger in a cake,
you can sort of trace which direction the finger was poking.
Yeah, imagine like a hundred-layer cake and you, like, shoot a bullet through it.
And then you took slices of that cake and you traced where that bullet hole was.
You could figure out what direction the bullet came from.
Yeah, there you go.
Just don't eat the bullet.
I was going to go with a JFK analogy, but I decided to go with cakes instead.
We got JFK, we got the boat.
The mystery gamma ray burst came from the direction of the Texas school.
book depository. It's all a big conspiracy theory. Yeah, yeah. The cosmic conspiracy theory.
Mm-hmm. All right. So this was detected just last year and who detected it? So it was detected all
over the earth. It was seen by Fermilat, which is a big collaboration of scientists from across
the world. It was also seen by the large high altitude air shower observatory in China. And then
there was a Russian facility that saw it also. And this observatory in China is only for very, very high
energy photons. And they've only ever seen a few photons very high energy. And this time they
saw 5,000 photons just from this one gamma ray burst. It's like 10 times as many as they've
ever seen in the entire history of the entire detector they saw in this one day, this one
period lasted about seven minutes long. Wait, meaning that it was visible to the naked eye or
you could only see it in gamma rays. You could only see it in gamma rays. You cannot see gamma rays
with the naked eye.
They're way too high energy.
And one of the most interesting and weird things about this camera rebirth is not just the
intensity, like the number of photons, but the energy of each individual photon.
So this thing also set a record as sending the highest energy photon ever seen.
This one photon had 18 terra electron volts, which is like much more energy than protons
have the large Hadron Collider.
And yes, it means it's a very, very high frequency, very short wavelength.
this is the highest energy photon ever seen by a factor of four.
So like, this thing is really far out there on the tails.
Wouldn't it mean that it's really close, right?
Because then don't photons kind of get stretched out as they go further out in space?
Absolutely.
It's very weird for a super high energy photon to come from really far away for two reasons.
One is, you're right, if it's coming from really far away, then as the universe expands,
those photons get stretched out.
They get redshifted, right?
so they get lower energy, which means originally it had even more energy.
The other reason is that the universe is actually not very transparent to super high energy photons.
As particles get really, really high energy, they start to interact with the cosmic microwave background radiation.
Like protons and other cosmic ray particles, if they're super high energy, they'll collide with the photons from the cosmic microwave background, the remnants of the Big Bang and interact and disappear.
The same thing is true with super duper particles.
high energy photons interact with those photons from the CMB.
So we shouldn't be able to see photons from really,
really far away because they should get absorbed by the universe.
So here we're seeing a super high energy photon from what seems like really,
really far away.
It's very weird.
So we can trace where the birth came from.
And when we look in that direction,
we see some galaxy where maybe it came from.
That's why you think it came from that galaxy.
But that's, you know, it's very speculative.
It's like, yeah, it's in the same direction in the sky.
right and that's the first thing we see there that doesn't mean it came from that
could have come from behind that there could be something else between us and
there all right we're really limited by our vantage point like it could be an alien
in between us and this galaxy with like a laser pointer that shoots lighting the
gamma ray direction and they're just messing with us yeah absolutely it could be or you
know it could be that it just came from something else and it happened to land here
on earth this one special photon happened to land here on earth at the same time as
this gamma ray burst, right? That could have been random. Well, or maybe it's not random. What if it's like
a phone call? It's like a voicemail. It's like in your hotel room when you ignore that
blip. Yeah, it's like it's an emoji. It's a text message that says, you up? Wow, it's a late
night booty call from aliens. Hopefully not a booty call, but hopefully it's a science call.
Family friendly. But you know, there's a lot of really interesting science that could be done with this,
because, again, people don't understand how a photon with that much energy could travel that far across space.
One fun paper I read suggests that maybe it wasn't a photon the whole time.
Maybe it converted to this weird theoretical particle called an axion.
There's this idea that maybe axiom particles are the dark matter,
and they couple a little bit to photons, and so photons can sometimes turn into axions.
There's a set of experiments called light shining through walls,
where people look for photons penetrating stuff,
the photons shouldn't be able to penetrate
by turning briefly or for a while into axions
and then converting back into photons
when they come near the earth, for example,
and hit our magnetic field.
So some people argue that this might be evidence
that this photon turned into an axon,
flew across the universe,
and then came back into photon mode so we could see it.
Whoa, that's a little too convenient, though, isn't it?
It's just hard to explain.
Like, we have no actual explanation
for this photon.
There is no way we should see.
It's like an impossible photon.
I mean, the most boring explanation
for this crazy photon
is that it's a mistake,
that we don't know how to measure
the energy of particles
with super duper high energy.
Because remember,
we're always reconstructing these things.
This is an air shower observatory,
which means you're not seeing the original photon,
you're seeing the particles
that turned into
when it slammed into the atmosphere
and created this cascade of particles
that are shining and flashing light.
Meaning it could have been something else, not a photon.
It could have been something else, not a photon.
Or it could have been something with lower energy.
You know, the uncertainty on this resolution is significant.
We should also say the Russian Observatory reported an even higher energy photon,
250 terra electron volts, like more than 10 times the energy of this one scene in China.
But the truth is, nobody believes them.
They're like, yeah, no, you guys messed up.
Let me get this straight.
We don't know what cost this burst.
We don't know where it is exactly.
We don't even know if it is a burst.
We know it's a gamma ray burst.
It was very, very intense.
But it has these special photons in it that really raise some questions.
Maybe we've mismeasured them, or maybe they're evidence of axiom dark matter or something else happening.
But there's a lot of uncertainty in these things.
And, you know, the frustrating thing in astronomy is you can't control these experiments.
Like if this was something you were doing in your lab in your basement or even with a large hadjunct collider, you could say, let's do it again and check.
but these are just things we're lucky or unlucky enough to see in the sky
and have to wait for it to happen again before we can convince ourselves it's real.
I wonder then we should maybe retitled the episode
because really we're just talking about the brightest flash we've ever seen.
We don't even know if it came from an explosion or an alien laser or alien phone call, right?
Yeah, or space unicorn farts.
Yeah, absolutely.
Yeah, a very focused space unicorn fart.
Maybe they are the aliens.
Whoa, I'm unifying the theories now.
That's how they make phone calls to their fart network,
in which case it is sort of technically a booty call.
People are doing a lot of work to try to understand this better.
They're trying to see, like, was there a jet of material that was emitted
by looking at the spectrum of light that comes in the gamma raybers?
They can try to get a sense for, like, what was in that jet?
Was it wide?
Was it narrow?
Did it have the kind of material we expect from a collapse?
What can we learn about the origin star?
Maybe there was something weird about the star that collapsed
that generated this incredibly bright source of light.
And so there's a lot of sort of conflicting studies still about this.
Some people say the jet was really, really narrow.
That's why I was bright.
Another study said, no, actually the jet looks like it was wider.
But, you know, there's a lot of questions.
This is the early days in understanding this.
But unless we're lucky enough to see a brighter one,
this is going to be a boat for a while.
Is it possible also that maybe was like focus somehow, right?
right because isn't there sort of lensing out there by dark matter or maybe other things could something
have lensed this light to make it seem more intense yeah that's certainly a possibility
there's some really cool studies to try to understand how much dark matter there is between us
and any point in the sky by looking for evidence of lensing we don't see lensing evidence in this
distribution but it's certainly possible we don't have a great map of where the dark matter is
in the universe and you know that's a fundamental limitation to looking at the
universe only from the service of one planet. Anytime you get a photon, you don't exactly know
where it came from, what happened to it along the way. And you have to try to untangle all of
these mysteries simultaneously, right? How much dust is there between us and there? How much dark matter
is there? How is the universe stretching? Is that even? Is that isotropic? Is there other weird
stuff going on? Simultaneously, we have to try to unravel these mysteries to explain this incredible
mosaic we see in the night sky. Amazing. But I guess,
maybe the overall message is that we've seen something that is brighter than what we thought was possible.
And it's pretty incredible that we're still doing that, right?
We're seeing things we didn't think could exist before.
Yeah.
And it's stunned astronomers.
I mean, astronomers are used to big numbers about the universe.
But even this one, sort of like you can tell it rocked them back on their heels.
Wait, it shocked even the bright ones.
Exactly.
Eric Burns, who's an astronomer who studies this kind of stuff, said, quote,
the energy of this thing is so extreme that if you took the entire sun and you converted all of it into pure energy, it still wouldn't match this event.
There's just nothing comparable.
Yeah, that's incredible.
Yeah.
Unless you consider farting unicorns in which case.
Anything's possible.
All right.
Well, an interesting exploration of a new universal or at least local world record of the brightest flash we've seen and its mysteries.
And one thing we do know is that the universe contains enduring.
mysteries and the more we look out there in the universe, the more we understand, and the more
we are shocked by what's out there. Yeah, and the more that we need bright people, like maybe
you, out there to figure out the mystery. He's talking to you folks, guys, not to me. We hope
you enjoyed that. Thanks for joining us. See you next time.
For more science and curiosity, come find us on social media where we answer questions and
post videos. We're on Twitter, Discord, Insta, and now TikTok.
Thanks for listening and remember that Daniel and Jorge Explain the Universe is a production
of IHeartRadio. For more podcasts from IHeartRadio, visit the IHeartRadio app, Apple
podcasts, or wherever you listen to your favorite shows.
The holiday rush, parents hauling luggage, kids gripping their new Christmas toys.
Then everything changed.
There's been a bombing at the TWA terminal, just a chaotic, chaotic scene.
In its wake, a new kind of enemy emerged, terrorism.
Listen to the new season of Law and Order Criminal Justice System on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
My boyfriend's professor is way too friendly, and now I'm seriously suspicious.
Wait a minute, Sam.
Maybe her boyfriend's just looking for extra credit.
Well, Dakota, luckily, it's back to school week on the OK Storytime podcast, so we'll find out soon.
This person writes, my boyfriend's been hanging out with his young professor a lot.
He doesn't think it's a problem, but I don't trust her.
Now he's insisting we get to know each other, but I just want her gone.
Hold up. Isn't that against school policy? That seems inappropriate.
Maybe. Find out how it ends by listening.
the OK Storytime podcast and the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
Get fired up, y'all. Season two of Good Game with Sarah Spain is underway.
We just welcomed one of my favorite people, an incomparable soccer icon, Megan Rapino, to the show.
And we had a blast. Take a listen.
Sue and I were like riding the lime bikes the other day. And we're like, we're like,
people ride bikes because it's fun.
We got more incredible guests like Megan in store, plus news of the day.
and more. So make sure you listen to Good Game with Sarah Spain on the IHeart radio app,
Apple Podcasts, or wherever you get your podcasts.
Brought to you by Novartis, founding partner of IHeart Women's Sports Network.
This is an IHeart podcast.