Super-Duper Novas with Michael Shara
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Chuck, it's great to have colleagues who are the world's expert on something.
Just arms reach down the hallway.
Yeah, I would not know what that is.
In this case, stars that blow up.
Cool.
That is so cool.
Coming up on Star Talk.
Welcome to Star Talk.
Your place in the universe where science and pop culture collide.
Star Talk begins right now.
This is Star Talk.
Neil deGrasse Tyson, your personal astrophysicist.
We're going to do cosmic queries today.
Chuck.
Hey, Neil.
Did you collect the Cosmic Query?
I did.
And they're not just random this time.
No, they are not.
They were solicited on the topic of stars that blow up.
Oh, and by that, we mean those nasty stars that are just mean to all the other stars.
Oh, that's not how that works.
I haven't checked the sociology of the galaxy lately.
There's a friend and longtime friend and colleague of mine who works right down the hall, who is one of the world's experts on stars that blow up.
Dr.
Professor, Curator, Michael Shara.
Mike.
Good afternoon.
Welcome back to Star Talk.
It's a real pleasure to be here again.
Did you guys realize he was our first hire when we rebuilt the Rose Center?
Really?
So 25 years ago, the Rose Center's been here 25 years, but we built the Department of Astrophysics to
Michigan.
We got Michael.
And now we can build around Michael.
And you came from the Hubble Space Telescope Institute.
I do.
So you and Hubble go way back.
I was there more than 40 years ago, and I was, in fact, the first
scientific hire without tenure who got tenure at the Space Telescope Institute.
So you were there
pre-launch.
That's the origin story of the
Hubble Institute.
I was hired there seven and a half, almost eight years before the launch of the telescope.
Wow.
That's like being on Krypton before
launched.
So that's on the campus of Johns Hopkins University
in Baltimore.
That is right.
Right, right.
3700 San Martin Drive.
Whoa, there it is.
And we were delighted that you were ready for a change and you came to join us here.
It's been 26 fabulous years.
The only condition of my hire was that I not blow up like the stars I study.
I'm still here, still having
compa tickets, I think.
I think that was in the deal that we cut with him.
Okay, that works.
So, Mike, tell us about...
stars that blow up.
First, disentangle the fact that the word nova and supernova looks like one is just a sort of
an extra version of the other, but they're two completely different things in the universe.
They are completely different things, but there's not just novas or novae and supernovas.
There are micronovas.
There are dwarf novas.
There are recurrent novas.
Okay.
Novas, supernovas.
sub-supernovas and hypernovas.
And they're all
once you get past supernova,
you know.
Well, if you find something that is more energetic
and brighter,
lasts longer and even more unexpected than a supernova, you got to give it a title.
Because you're already titled super to supernova.
Because at the time you titled that, that was that super.
That was the ultimate.
And now we know there are things that are a lot brighter and even more, in a sense, explosive than supernova.
So had I been around
at the search for that new term, I would have called it super dupernova.
Way more fun.
And when some of me and my explosive star friends are sitting around over a beer, that's what we refer to as.
Superdupernova.
Super dupernova.
So let's back up.
So the stars, nova literally from Latin means new.
Right.
Yet it's the star at the end of its life or at the end of it's long lived a life before it goes nova.
so it's really misnamed long before it goes supernova there's a real difference because novas let's let's start with novas let's okay let's do in a sense the simpler thing novas are stars that explode but don't die gotcha every nova explodes not just once or twice but thousands of times.
Oh, it's a Christian Bale star.
These are things that explode over and over again.
And there can be
years between the explosions of novas.
These are called recurrent novas.
Or centuries,
millennia, even a million years,
because
something has to be rebuilt.
The explosive part has to be rebuilt, and then it explodes again.
Because the star's still there.
The star, the underlying star,
and it turns out that every nova is a binary star.
So the stars, plural,
are still there after the explosion.
Did you say every nova is a is a binary system?
That's correct.
So
does that mean that one star is feeding another star?
That's exactly right.
And feeding may not be exactly the right word.
You might think of it as a kind of cannibalism.
Ooh.
Involuntary feeding.
Oh, my.
Of one star by the other.
Wait, and it's worse.
Wait, wait, but the big bulbous star that's handing over the matter right it was asking for it because it was it's it's it's it's in in actually in its space in its space it's in its space up in it up in the space up in the space and the little star is like why are you in my grill man that's that's exactly true i'll give you that it's also worth remembering that there's a kind of zombification going on here because the little star is almost always what we call a compact degenerate object either a white dwarf or a neutron star or a black hole.
Hi-ho.
Listen, I've got a gambler problem.
What can I say?
So it's not just you have some overbearing, bulbous, hasn't been able to control itself star involved, but it's actually being eaten
by this
nearby very compact, very simple.
So
it actually takes two to tango.
Very much so.
Right, okay.
Tell me exactly what's happening.
So the secondary star, is that what it's called?
The big one?
It's sometimes called the donor, sometimes called the secondary star.
That star also has to be in a late stage of its own life to become a red giant and swell to become so large to overspill the gravity.
boundary that happens in some cases but it doesn't actually have to be a red giant it can be a main sequence star still burning hydrogen just like
just like the Sun.
Our Sun, yeah.
Identical to the Sun in every way.
And the reason that it's starting to
accreted onto or it's feeding the companion is just that it's so close that as a little bit of it expands, just a tiny bit of expansion during its evolution,
the nearby star has enough gravity to be able to immediately vacuum off, suck off any material that expands beyond a certain radius.
So it doesn't have to be...
It doesn't have to.
Okay, gotcha.
Wow.
So
have we ever taken a look at these systems and
seen like planetary systems around them?
We've looked.
It would be an extremely unpleasant environment for any planetary system.
Nobody has found one.
Okay.
Even if it was there, it would be extremely hard to to find because there's a lot of light being given off by these guys.
They're intrinsically
the accretion disk, the donut of material around the compact star is quite bright.
It flickers like crazy.
And any planet would be, of course, thousands of times or hundreds of times less massive than the two stars.
When you say the disk flickers, is that every time a little bit of matter hits it, you get a little bit of bright spot?
You have stuff being sucked off the donor into a donut-shaped accretion disk, as it's called, around the compact object.
And as that stream of material bangs into the donut,
it causes flickering continuously on a time scale from minutes to seconds, probably down to milliseconds.
And the donut...
is a mechanism to feed the compact object.
That's okay.
So now, why doesn't it just explode as soon as stuff hits the surface?
You need to not just get a little bit of hydrogen onto the surface, because if you put a bit of hydrogen on the surface of a white dwarf, it can just sit there.
The hydrogen doesn't feel the need to explode until it reaches a certain density and temperature.
And that critical density and temperature mean that in the case of a, let's talk about a white dwarf star, just for concreteness, that's what most novas are, white dwarf stars.
These are guys that are about the mass of the sun, so several hundred thousand times the mass of the Earth, but they're only the size of the Earth.
And how much hydrogen do they need to accrete in order to become explosive?
Well, because they're the size of the Earth, about 8,000 miles across, they need to accrete about a mile of hydrogen, so about a Pacific ocean's worth of hydrogen onto their surface.
At that point, the density and pressure at the bottom of the Pacific Ocean of hydrogen
is about 10,000 grams per cc, so about a thousand times denser than lead.
Temperature reaches 40, 50 million degrees.
At that point, the hydrogen becomes highly explosive.
Boom.
You blow up and you get to be about 100,000 to a million times as bright as the sun.
Well, actually, let me clarify something.
Yep.
Hydrogen as a gas
is explosive.
So that's not what you meant.
Right.
Okay, so be precise there.
It is not the kind of explosion that you're thinking of in the Earth's atmosphere where hydrogen combines chemically with oxygen.
All the humanity.
From the end of Berkeley.
Yes.
The last dirty.
Sorry for going dark there, guys.
Sorry.
That's it.
The last dirigible ever filled with hydrogen.
We're talking something 100,000 or a million times more energetic because we're talking nuclear reactions.
So instead of the hydrogen combining with oxygen, we're talking about protons smashing into each other, overcoming the
charge barrier between them,
fusing together.
Nice.
Basically a hydrogen bomb.
And once you do that, once you become a million times as bright as the sun, we can see you not throughout the Milky Way, not just throughout the Milky Way, not just in the Andromeda galaxy, but I've tracked more than 100 novas in the Virgo cluster of galaxies, 50 million light years away.
Wow.
So these become really, really bright objects.
So I love the idea that I've never heard it put before when you say the Pacific Ocean
amount of hydrogen because it's also pressure, right, that you need, right?
That's exactly right.
Yeah.
So it's like the same way as you get to the bottom of the Pacific, you would be crushed because of the pressure.
It's that same pressure that is causing this ignition.
And the pressure, of course, is causing the density to be higher and higher.
The higher and higher density pushes the protons closer and closer together.
Which ordinarily don't want to get together
because they have the same charge.
Science is amazing.
I'm sorry.
It's just so damn cool.
It's just so cool, man.
Let's put a pin in that.
Now let's go to supernova and then we'll go to our Q ⁇ A.
It used to be thought that there were two kinds of supernovas.
Let me guess, type one and type two.
That's precisely right.
Two types.
And of course, it turns out that the type one supernovas are in what we call population two
galaxies.
And the type two supernovas, just the opposite.
One of my early books, there's a chapter titled The Confused Person's Guide to Astronomical Target.
Nine.
That was the name of the chapter.
It should be like require a meeting, I think.
Yeah, exactly.
Yeah.
So now with almost a century's worth of study of these things, we know that in very, very first,
very first principles, the broadest way of looking at these supernovas are that they're either what we call core collapse supernovae, that is massive stars where
the inner part of the star, which holds itself out against the gravity of the rest of the star,
loses that pressure.
Somehow that inner part of the star collapses in on itself.
And when it does so, the whole star implodes, bounces on the inner part of the star, and then much of the star is blown away.
So that's a core collapse supernova.
And the other kinds are what are called single or double degenerate supernovae.
And these are guys,
stars that are mostly white dwarfs,
that have also lost their source of pressure in their centers, collapse down to become probably neutron stars in most cases,
releasing enough energy to blow off the outer envelope.
And these two very different kinds of supernovas
have very different properties in terms of what we see in their spectra, what we see in the ejecta, the stuff that gets blown off of the two stars.
So we know that they're two very different things.
And within the core collapse supernovae, they can be anywhere from
20, 30, 40, up to 100 times the mass of the sun.
While the other ones, the degenerate supernovas, are somewhere between about 1.4 and about three times the mass of the sun.
So much lower masses.
And those are the ones that also don't pay child support.
Never.
Yeah.
But they are the ones that let us discover the dark energy.
Nice.
So as I'm hearing you describe this, I can't help but
recall to mind like neutron stars because that's basically what you described, if I'm right,
a neutron star.
And then if it's spinning very fast, it's then a pulsar, right?
If it's spinning very fast and has a magnetic field.
Oh, okay.
That's an extremely important part of it, which it almost certainly does.
And the magnetic field can't be aligned with the axis of rotation.
Perfectly.
It's got to be tipped.
You get all of those things.
You're going to end up with a pulsar for a while.
For a while.
Maybe 100 million years.
Listen, that's just a blink.
That's a blink to an astronomer.
Wow, look at that.
After some time, after that 100 million years or so, it's going to go radio quiet.
It's not going to be as interesting.
So for every pulsar we see wandering around out there, there are probably 100 quiet or listened to.
We can hear the beep beep beep.
There's probably 100 quiet ones.
Now, here's my last question because I know I don't want to.
That's not your last question.
I know it's never is, but I don't want to take up time from the people.
Are you about to ask a question?
Yes.
Where's your Patreon?
Oh, come on now.
I'm asking on behalf of, let's see.
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This is Star Talk with Neil deGrasse Tyson.
Everything you just said seems to me like
the
same things in the process of creating a black hole, except you need a lot more mass.
And then what happens in the end is that we can't see into it because at some point the gravity is so great that light can't escape.
If that is the case, and this process is the same, just bear with me.
Why can't we study this to kind of know what's happening inside of a black hole?
The answer is a few parted.
Okay.
So, first of all,
we only know for sure of one kind of all the core collapse supernovas, because there are different kinds of flavors.
So think of them as ice cream, there's chocolate, vanilla, strawberry, raspberry,
so there's many, many, many different subtypes of the massive star supernovas.
We know
of the ones that are called the type 2 plateau supernovae, that they have red supergiant progenitors.
That is the stars that make these kinds of supernovas
and almost certainly end up as black holes, as modest mass black holes are red supergiants.
But do you get a supernova with the black hole or not?
Or does everything just get sucked in?
Some of the stuff gets blown off.
We think,
yet.
And the reason we think that is we've seen lots of supernovas and we look at them.
We've observed lots of supernovas.
And when you look really, really carefully, a century later, two centuries, a thousand years later, we see a supernova remnant.
We see a big expanding cloud of gas.
The Crab Nebula is maybe the classic example.
Can you also measure the rate at which the gas is moving away?
We can.
And turn the clock back and say in the 1054 for sure.
Absolutely.
Very cool.
That's how we know beyond the shadow of a doubt.
And we know that there is a very, very bright, rapidly spinning neutron neutron star in the center of that supernova.
There is a beautiful pulsar there too.
So there we have absolute proof, as much as you can prove anything ever in astrophysics, that you had an intermediate mass star, maybe 10 or 15 or 20 solar masses, that collapse down to give you a spinning neutron star and the supernova remnant.
But there may be dark supernovas too.
There's a good case to be made for some stars, very, very bright luminous stars that just go
and disappear out of the universe.
I've seen a video of that.
I mean, an animation of it.
Yeah.
It's scary, actually.
It's like the whole thing gets flushed down its own toilet.
And there's no, you know.
Like a snake eating itself.
Yeah, yeah.
If you will, except that it's not gone.
Right.
The black hole is still there.
Right.
And if you are a highly adventurous astronaut racing through the universe and you don't have the right sensors, you're going to go right down it, right right down the throat of that snake that swallowed itself, and you're not even going to know it.
It's just going to take you right down.
Which of these is responsible primarily for the heavy elements in the universe?
Probably a combination of them.
A combination, okay.
So one kind of nova that we didn't mention before are kilo-novas.
And the reason that they're called kilonovas is because they're about a thousand times more energetic than a nova.
which is about a million times the brightness of the sun.
So these are about a billion times the brightness of the sun.
And a supernova, which is about a thousand times brighter than a kilonova, so you could call it a mega-nova, except we call it a supernova.
And then there are things that are 10 to 100 times brighter than that, and those are the hypernovas.
And there's different mechanisms, different things that are going on in each case.
So...
Wow.
But you have that inventory, so we can account for the elements in the universe.
Yes, and we have a fear idea just by taking spectra, breaking up the light into all its components, and measuring what's coming off in supernova remnants, how much iron, how much silicon, how much nickel is being produced in different kinds of supernovas.
So certainly some of the core collapse supernovas are producing certain kinds of elements.
Probably the collapse of the degenerate objects is producing much of the iron in the universe.
And ordinary novas are probably producing a good fraction of the nitrogen in the universe.
So every time you take a breath, you're breathing in some of the excreta.
Every breath you take.
Every breath you take is
some of the excreta of a nova.
Well, when you say it like that,
it's not so pleasant.
I was about to say, thanks, supernova, but now I'm like,
so what you got here?
All right, here we go.
Let's jump into it.
This is from Dipin.
Hello, Dr.
Tice and Dr.
Schauer, your lordship.
First, we're taught that matter in neutron stars is strange.
Then we say that collision of neutron stars creates heavy metals like gold and platinum.
How are these normal metals created from strange matter?
Great question.
The answer is that while the matter inside a neutron star is at not just strange, but insane sorts of densities.
One with 13 or 14 zeros after it, grams per cubic centimeter.
So
quadrillions,
trillions or quadrillions of grams per cubic centimeter.
Once the kilonova has exploded,
Maybe some of it fallen into a black hole, but some of it's been blown off, that expanding matter starts going down in density.
And so the
free neutrons inside the neutron star start combining with each other.
Some of them start decaying into protons.
Neutrons and protons combine to make nuclei.
And that's how you get ordinary matter because you get out of the incredibly dense state inside the neutron star.
You've escaped.
You're free to become yourself.
You're free to become Golder Play.
That's right, Dad.
Oh, that's very cool, man.
Great question.
All right, this is Stacey Hughes.
Hello, all.
This is Stacey Hughes from Nebraska.
I have heard somewhere that large stars are going to stop being born before other stars.
If that is true, how much sooner than the last stars dying out will the last supernova be?
And what types of stars will be born after the last supernova?
And will we still be here when that happens?
Let me take that last part for you.
Don't look like it.
So go ahead.
Given the rate at which humans have been developing technologies capable of destroying all of us, I'm not sure.
I'd say we have maybe a 50-50 chance.
Okay.
Okay.
But if we make it through the next century or two, maybe we'll get smart enough or maybe we'll disperse away from the Earth and be able to hang in there.
Let me answer your question about the most massive stars.
When we look out in the Milky Way galaxy,
we see large clouds of gas and dust,
including things we call giant molecular clouds.
And these are the objects that give birth to new stars.
And we see the same kinds of objects in nearby galaxies, and we can image them in great detail with the Hubble Space Telescope or the James Webb Space Telescope.
And we see clusters of thousands of stars being born now throughout throughout the Milky Way, throughout nearby galaxies.
And there are almost always some really, really luminous, very, very massive stars in these youngest clusters, up to about 100 times the mass of the sun.
Will this eventually stop?
Well, we see galaxies where this has stopped, because when galaxies crash into each other and merge, most of the gas, the hydrogen gas, the stuff out of which stars is born, much of it is liberated.
It's blown out of those galaxies.
We're left behind with an elliptical galaxy that doesn't make many stars anymore.
And so at some point, it's possible, in fact, likely, that every galaxy in the universe that has hydrogen in it will have lost all or most of that hydrogen.
And when that happens, star formation is going to ramp down and eventually stop billions of years into the future.
But not right now.
Will we be around billions of years in the future?
No idea.
Come on.
Cannot tell you.
Yeah, I can.
I can tell you.
I can tell you right now.
You know, you know.
You have the answer now.
I got the answer right now, Stacey.
That's a great question, though.
And these gas clouds that you see, are these the same as stellar nurseries?
Is that what we know?
That's exactly right.
The nearest prominent one, you can see it with the naked eye, is the Orion Nebula.
Underneath the three stars in the belt, there's this lovely glowing cloud.
And if you're in the southern hemisphere, they're above the belt.
That is true.
And there's one.
It's so like us to hit below the belt.
And there's one O-star, one of those massive stars that's doing all the ionization, all the excitation.
It is the guy that is responsible mostly for the central part of the Orion Nebula looking like it is.
If it weren't there, it'd be a much less interesting thing to look at.
Wow.
That is super cool, man.
All right.
This is Christopher Peffers.
And Christopher says, hello, Dr.
Shara.
Dr.
Tyson, Lord Nice, Nice, Chris Peffers here from Charleston, Indiana.
Dr.
Shara, you've spent decades studying exploding stars and binary systems, some of the most extreme objects in the universe.
For people who might think space is just empty and still, can you walk us through what happens in a closed binary system where one of the stars steals matter from another, eventually causing a supernova, a nova, or a, or even a supernova?
What does that cosmic drama look like?
And should everyday people even care about these distant events?
Do they help us understand our own sun or even where the elements that make up life on earth come from?
Thank you for your work, sir.
There it is.
Well, first of all, it's my pleasure.
I appreciate the pat on the back, sort of, the verbal pat on the back.
I do it.
The reason I've spent decades doing this is because I love it.
Astronomy, in some sense, is my hobby.
The fact that someone's willing to pay me to do it and to teach
about it.
Take your hobby, make it a career.
And you'll never.
Was it the history of that?
Right.
Well, yeah.
You'll never be someone.
No, you'll never work a day in your life.
You'll never work a day in my day in your life.
And it's been a joy.
And in some sense, I haven't worked a day in my life because it's always been fun.
It's always been great.
That's pretty cool.
I get to work with lots of bright young people doing their masters and PhDs and work with them all the time.
So it's a glorious way to spend one's life.
Okay, let's zoom in on one of these systems, one of these binary systems.
And I'm going to pick a particular system
that you're going to be able to see with your naked eye
next year or the year after.
Okay.
Okay.
All right.
Relatively short period of time.
I bet he's talking about T.
Corona Borealis.
And Neil has just thrown away.
Don't tell anybody, but I think
it's quiet.
And when he says it, just
act surprise.
Axe surprise.
Okay.
Yeah.
So what is it?
So there is a star called T Corona Borealis.
Surprise.
That is going to get brighter than the North Star, brighter than Polaris.
Wow.
Either tonight or tomorrow night or sometime in the next year or two.
Okay, just I have to jump in here.
Okay.
So
I don't want to cast shade on how bright it's going to get, but Polaris ain't that bright.
Okay.
Our North Star, which I've heard you say this.
Even nine out of 10 people, you say, what's the brightest north thing?
They'll say
it is not in the top 10.
It's not in the top 20.
It's not in the top 30.
It's not even in the top 40.
Yes.
Okay.
So I just put that out there, right now.
And
the core bore, what does that reference?
Corona borealis, Latin for a northern crown.
And it is a constellation, a little grouping of stars that looks like a semicircle.
A crown.
Okay.
Gotcha.
Actually, a tiara would be that, right?
That's a better term.
Exactly.
Much better name.
So is there a crown in the southern hemisphere?
There is Corona Australis.
Okay, good.
So that's why we specify the Borealis.
That is correct.
Yeah.
Okay.
So pick it up from there.
We saw this star last erupt about 79 years ago.
And then 80 years before that, we saw it erupt as a nova.
And each time it became about second magnitude.
And one of my colleagues, Brad Schaefer, has made a pretty good case for it having erupted 80 years before that.
And then he even points out some possible evidence for an eruption in the 1200s.
So this is a star.
This is a recurrent Nova.
Wait, nobody was looking up in the 1200s.
They were just trying to not...
whatever.
Not star to death.
Eaten by dragons or not starve to death.
Or die of the bubonic dead.
No, no, no, there were people who actually did notice changing stars, things that were wild.
And of course, there were no electric lights in those days.
They had lots more stars to look at.
There were.
Actually, sorry, it was the 14th century, which was the only century where the population of the world was lower at the end than it was at the beginning from the bubonic plague and all of this.
Black Death will do it every time.
That's why I can't stand it.
They called it the Black Death.
Of course, the most deadly of deaths has to be the Black Death.
Go ahead.
Okay.
I'm being silly.
Go ahead.
No worries.
So this star,
this massive white dwarf, is cannibalizing its companion, which is a, in this case, a red giant star.
Authentic red giant.
This is an authentic red giant.
Can you see both stars when you look at them?
Are they too far away?
You can see neither.
It is roughly 13th magnitude in quiescence.
So if you look
with a terrific pair of binoculars, you still can't see it.
You need at least, if you want to see it with your naked eye or with your eye, you need at least, say, an eight or a 10 inch telescope to be able to see it.
A really good backyard telescope
would catch this.
We'll see it when it's in quiescence.
And it's going to jump in brightness approximately 100,000 fold
to reach roughly the brightness, a little bit brighter probably than Polaris for a few hours.
And then it'll fade away.
And then on a time scale of a week or two, you won't see it again.
And you won't see it again for another 80 years.
So, when I was in the Pacific Northwest, I took a photo of your star, and I don't know if I got to show it to you.
Did I?
Did I ever show it to you?
I think you might have.
Because, you know, there was a chance it could have blown up while I was looking at it.
Exactly.
And then I'd be the first to have seen it.
Right.
Or at least record it.
I'd have been the first out of the box on that one.
Yep.
Everyone wants to be the one to see it starting on its roster.
Of course.
And so people have little charts.
And okay, there's T.
Corona Boreal.
So somebody's watching this thing every night.
Of course.
Someone is watching it basically every four hours a day.
24 seconds.
Because half the world is dark at any given time.
And we got people everywhere.
Of course you do.
There are tens of thousands of so-called amateur astronomers who are every bit as professional as professional astronomers.
In that community,
it is a badge of honor.
to say, I am an amateur astronomer.
If you say that, you can ask them any question about the night sky and they'll have an answer.
Even some of my colleagues wouldn't know because they know the night sky.
They're out there every night as I was when I was, you know, had my backyard telescope, except my rooftop.
There's no backyard in the Bronx.
I was hauled to the roof.
So the thing for me that is most exciting about T.
Corona Borealis
is that as a recurrent nova, it was predicted, and there were only 10 recurrent novae known in the whole Milky Way
about a decade ago.
It was predicted that, boom, you blow off a shell of matter, then 80 years later, boom, you blow off another shell, another, another, another.
The stuff doesn't all come off at the same speed.
Some of it comes off at high speed, some at a lower speed.
So what that means is when the next shell goes off,
some is going to overcome, it's going to, the fast stuff is going to overcome the slow stuff.
Bingo.
So you're going to have shells colliding with each other.
Shells colliding, Jerry.
No, that's amazing.
And so it's going to be a traffic pileup.
It's like, you know, one car running into another.
And if that's right, that hasn't just been happening for 80 or 160 or 240 or 320 years.
It's been going on for thousands or tens of thousands of years, which means you've got hundreds or thousands of shells piled up on top of each other.
That means you should have a super shell, a super remnant surrounding t corona borealis where it's all where it the fastest stuff is plowed onto itself right a bulldozed its way through but that's not all wait wait there's more because as that shell builds up in mass, it's also acting like a snowplow, plowing up all the stuff in the interstellar medium in front of it.
The stuff that's there anyway as bystanders.
Is going to get mowed over and is going to be incorporated into that super shell.
So there should be a super duper shell around it, and we've just found it.
Oh,
he buried the lead.
You heard it here.
So we've been using a gorgeous new, not expensive telescope.
Oh.
The kind of telescope that so-called amateurs use, refracting telescopes.
Six of them bolted together in parallel.
and we stared at T.
Corona Borealis for about a hundred hours.
They're not in darkness for a hundred hours.
I just want to make that clear.
Oh, okay.
Yeah, they get the dark stuff tonight.
Right.
They close the hatch and then tomorrow night, pick it up and get it.
Get back at it.
Okay, back at it.
Okay, go.
And so we actually have thousands of images taken over more than a hundred nights of T.
Corona Borealis, and we add up all those images.
And we took pictures through filters that only transmit the light from hydrogen, only transmit
the light that comes from nitrogen ions, sulfur ions, and so on.
And we found a super shell surrounding T.
corona borealis that's about three times the diameter of the full moon.
That's fabulous.
So it is a degree and a half on the sky.
And you might then think,
well, when T.
Corona Borealis goes off, it's going to be like a flash bulb going off in the room, in a room full of little mirrors.
It's going to be like Christmas lights going off as this flash of light propagates outwards.
Echoes off the material.
That's super shell.
One would hope that that would be true.
That's amazing.
It's probably not.
Oh, no.
So the downer is we published in a paper that just came out a couple of months ago saying
there's not going to be fluorescence.
So the atoms themselves are not going to light up because they're too far apart and there aren't enough of them that it's not going to be bright enough to detect.
Now, maybe, just maybe,
if there was dust,
little grains of silicon and carbon and other what we call refractory elements, high-temperature stuff, little grains that were tossed out in the last Nova eruption, the one 80 years ago, those might reflect enough light for us to see as a light echo.
And you know that a day or two or three after this goes off, the Hubble Space Telescope is going to get pointed at at the James Webb Space Telescope.
We're very good about that.
Something happens.
Everybody
comes together.
We are the most
information.
We are the most come together.
It's always about a collabo.
Always, especially since not every telescope will observe it in the same way.
So you get different kinds of data coming together.
I always say the only people to collaborate more than rappers are astrophysicists.
So, Mike, on my iPhone, I controlled a digital telescope when I was in the Pacific Northwest.
Didn't even leave the comforts of the living room when I did this.
See,
he's old school.
He's like, what?
You didn't ascend the mountain?
You did not suffer for that image?
I've been up in the prime focus cage of telescopes for nights at a time.
Tell me about it on your rocking chair.
So this image, I found it, but it was behind a very modeled tree.
And so the digital telescope tracks it.
But so the tree ends up blurred as it's tracking the the actual object so it looks it's a very undistinguished dot on my on my picture had you caught it near its maximum you would basically have saturated the image yeah all of the image would be just one bright point of light wow but there's no saturation anymore because this knows what it's doing it takes 10 second images yes and then stacks them right yeah in the old days you're exposing overexposed
yeah right yeah now you don't have that problem yeah you're getting all separate images
you stack them and add them and you get it.
Keep going.
All right.
Keep going, man.
This is really cool stuff.
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This is Joel Bradley and Joel says, greeting, Dr.
Tyson, Dr.
Shauer, Lord Nice.
Joel here from Geelong, Australia, and I have a question regarding our favorite pre-supernova star, Betelgeuse.
Whilst I understand that life of a star is extremely long from our perspective, how is the timeframe for Betelgeuse going to supernova between now and 100,000 years?
Is there any sign that will warn us of it happening in our lifetime?
Or will we just look up one night and go, oh, wow, look at that!
There it was.
There it is.
It was.
What's the life expectancy of Betelgeuse from birth to death?
Something like a, well, the star itself, if you consider the main sequence lifetime,
probably a few million years.
Got it.
Okay.
Okay.
So it was hydrogen burning for a good fraction of its lifetime, maybe a million years, maybe two, three million years.
When it's astrophysics speaking, she means hydrogen fusion.
Right.
Of course.
So Betelgeuse was initially as a very massive star fusing hydrogen into helium.
Then it left the main sequence, ascended the red, and then the red supergiant branches.
Ran out of hydrogen needed to do something else.
It needed a new source of energy, otherwise it was going to collapse.
The core got dense enough and hot enough for helium to start fusing into carbon.
And helium has...
Two protons in its nucleus.
Now you got to get two protons connected to two protons.
You got to be hotter than whatever you were for hydrogen.
Look at that.
Typically, you've got to be in the 100 million degree range range instead of the 20 million degree range in order for that to happen.
Okay.
So it is really hot down there in the core of Betelgeuse.
Betelgeuse has only got, probably in the best case, 100,000 years to go, but it might be tomorrow.
Okay, that's a really bad prediction.
Can you do better than that?
50 years ago, the prediction would have been.
We don't know why it's a red supergiant.
So we have gotten a lot better.
Yes, we would love to do better.
And the answer is if you give me a money.
We should appreciate how far we've come.
Even in our ignorance.
If you give me enough money, I will build a detector that will tell you several days in advance when it's going to go off.
Nice.
And what is that detector going to be?
Well, it's going to be the biggest...
baddest neutrino detector that's ever been built on Earth.
Right now, we've been super clever, we, meaning physicists collectively, not me, have built enormous detectors using cubic miles of seawater or ice.
The ice cube detector, for example, in Antarctica.
In Antarctica, and a gorgeous detector right near Sicily, a huge underwater detector.
And the wrapper Ice Cube goes down there and performs for the scientists.
But if we could build a detector that would say, oh, a thousand times the volume.
So instead of a mile by a mile by a mile, we'd love to build something that was 10 miles by 10 miles
by a few miles at least.
We'd have a thousand times the sensitivity.
Now, why do I care about neutrinos?
Well,
as the star is right near the end of its lifetime and just about to flash off, it's not just going to...
Do you see the light?
Do you see the light?
Yeah.
It's going to burn the carbon into magnesium, the magnesium into heavier elements, all the way up to iron.
And you're going to get a great flux of neutrinos neutrinos coming out of the core of the star in the last few hours, maybe days
of the life of the star, certainly in the last couple of minutes.
And then during the implosion, you're going to get another blast of neutrinos.
So these will come out of the star before anything else.
Okay.
But they're not going the speed of light.
So not.
It doesn't matter.
And the reason it doesn't matter is that Betelgeuse isn't that far away.
We're talking hundreds of light years.
We're not talking millions or billions of light years away.
And as a result, the difference between the speed of the neutrinos.
99.9, many nines percent the speed of light, the difference in speed between the neutrinos and the gravitational radiation
that will be
moving exactly at the speed of light.
And we have something that could detect that if it happens.
We have several detectors, at least three up and operating now that are going to detect those gravitational waves.
Are they all collectively LIGO, or is it just the American ones called LIGO?
They're collectively called the
LIGO, and each one of them has its own name.
For example, the Italian one is referred to as Virgo.
But
the LIGO, if you will, the LIGO assembly
is the three telescopes.
We get the gravitational waves,
and they will come at the same speed as the explosive light, I presume.
They're going to precede the light.
Oh, because you have the collapse.
You have the collapse, and then you got to expand again to get big enough to have a photosphere, a radiating surface big enough.
So it's going to be tens of minutes to tens of hours before you see it in the optical.
This is going to be amazing.
You'll see them right, one right after another, each of these sequence of events.
So we're going to see the gravitational radiation and the neutrinos arriving almost simultaneously.
We may get lucky and see a few of the early neutrinos coming a few seconds or minutes early.
That would be just in the last gasps of, oh, I'm just, I'm finished my carbon burning.
I'm going to do my magnesium burning.
That didn't help me.
I'm going to do my
silicon burning.
That helped me even less.
I'm going to do my iron burning.
So you get more and more frantic.
I've never seen you imitate a star before.
That's good.
That was very good.
That was a dying star right there.
And so because what he's doing is the star is trying to not die.
Right.
And so it's finding
everything it can do.
And if it can't, if there's not enough, it's going to collapse on dead.
And so maybe in that last minute, we'll start seeing a neutrino here, another one, another one, another one, and then tens of thousands of them are arriving.
And that's going to be the harbinger that's going to tell us supernova coming, supernovas coming from there, that direction.
If we have all three detectors, you can triangulate back.
We can triangulate to about plus or minus a degree.
Okay.
You know, a little bit more than the area of the full moon on the sky.
Yeah, but how many supernova progenitors are in the area of a full moon on the sky?
We typically get,
you know,
I mean,
in a square degree, we've got millions and millions of stars.
You don't know which one it is, but if you triangulate back to that one square degree where Betelgeuse is...
Yeah, and Betelgeuse is in the middle of the thing.
Right.
That's pretty much it.
You're going to go, whoop, whoop, whoop, whoop.
Turn on your alarms.
So
how bright will Betelgeuse get?
Because it's already bright.
It's like, what is it?
It's zeroth magnitude.
What is it?
Maybe minus.
Something like that.
It's certainly one of the 15, 20 brightest stars in the sky.
Way brighter than the North Star.
Once again.
So right now, currently, it's maybe a million times, yes,
the luminosity of the sun.
Okay.
But it's going to go to at least 10 billion times.
It's going to get at least 10,000 times brighter.
Wow.
115 magnitudes.
It's going to be visible in daytime.
Oh, it's certainly going to be a daytime thing.
It's going to compete with the full moon for brighter.
That's great.
Polycaster's shadow.
Oh, my gosh.
Joel, there you have it, my friend.
If you have a neutrino detector,
you will know exactly when this is going on.
If you get the neutrinos and you get the gravitational waves at the same time, just know, Elizabeth, I'm coming to join you, honey.
Betelgeuse is about to kick the bucket and you can watch it.
So that's
one good piece of news.
I mean,
you're headed in absolutely the right direction.
I don't want you scaring anyone, though.
You don't need to go down to your basement or your sub-basement.
Because even though there are going to be lots of high-energy neutrinos coming and whacking you, none of them is going to hurt you.
There aren't going to be enough gamma rays to fry our ozone layer.
Or make you the Hulk.
Or make you the Hulk or give you a sunburn.
So don't worry about that kind of stuff.
It's just going to be something ultra cool that you can walk out and see something that really nobody has seen since the 1600s.
We had two supernovas almost.
Kepler had one.
How bright was Kepler's supernova?
It was also the same kind of brightness, maybe not quite as bright as that.
In the daytime?
It was seen in the daytime probably for a month or two, but I got to go check that out.
So, let me ask you both of this then.
The most famous star in the night sky and also reportedly shone during the day, the star of Bethlehem.
Do we have any real record of what that was?
Go on, ask the Jewish man about the star of Bethlehem.
Go ahead.
So, my forefathers
did not draw a diagram or a map of where it was.
In fact, this only appears in the New Testament
as a star in the east.
Star in the east.
You know, that's a little
that is maybe better.
Well, we can go back to the people.
That's all.
That's the best info available.
That's it.
Well, we can try and cross-correlate it because
while the astronomers in the ancient holy land were not quite up to the task,
there were three sets of astronomers who were up to the task and really were doing their jobs on a night-by-night basis.
And these are the imperial astrologers of China, Japan, and Korea.
Okay.
who were looking at the sky every night as harbingers either.
Of anything, good or bad.
Yeah.
Good or evil yeah because clearly the gods were up there right and the emperor was a demigod right so whatever was happening to the gods was affecting the emperor so we'd better watch out really carefully and write down what was going on and so from about 300 BC, but certainly from 0 BC onwards, there are pretty good nightly records in all three kingdoms.
And the star of 1054, the, what's today, the Crab Supernovas?
The Crab Nebula.
The Crab Nebula is detailed in great detail, wonderful detail in all three kingdoms records.
Wow.
So we know all about it.
So we know that it took place
on July 4th, AD 1054.
And astrophysicists to this day celebrate with fireworks.
I just want you to know.
You see us
launching fireworks?
That's what's going down.
That's so funny.
So you'd like to look for a.
So they would have had records for sure.
If there had been a really bright supernova
or a really bright nova,
a bright nova, a nova that's only, say, a hundred light years away.
And there are stars that are capable of becoming novas only 100 light years away.
That is an easy star that can become brighter than Venus.
So not quite a middle-of-the-day, scary you have-to-death brightness, but still pretty bright.
Still pretty bright.
So you got to go look really carefully at the Chinese, Japanese, and Korean records from, say,
minus 10 to plus 10,
you know, AD,
and there is no good candidate.
And there's no good candidate.
Okay.
Wow.
And by the way, planetariums historically always had a Christmas show of the star of Bethlehem.
And was it a planetary alignment?
Was it Venus?
Was it this?
Was it that?
But it really wasn't any of those, right?
And that's kind of a disappointing ending to a planetarium show.
But we got so sick of the show.
I mean, it was just not, there was no science in it.
Yeah.
And so
in the parlance of planetarium, you know what we call it?
The War on Christmas?
No.
No, it was tradition.
People come to see that and they go to the Roquettes.
Right.
And that would be the holiday thing.
That makes sense.
No, but it became known as the SOB show.
SOB standing for Star Bethlehem.
There you go.
So we now have the technology.
Astronomers now have the technology to once and for all answer the question.
Okay.
And I'm going to tell you how you heard it here first.
All right.
Using the kind of telescope I described, the one that found the star show.
Was there a star?
Star Bethlehem.
Was there a transient?
Was there a bright nova or supernova?
Right.
Within, say, 10 years of zero AD.
Yes.
And we can actually answer that question now quite definitively.
And within five to ten years, certainly within 10 years, we're going to be able to give you that answer quite definitively.
Because you could.
Because you are looking right now.
Because you're going to, because if it was something that exploded, you'd be able to see the remnant that's 2,000 years old.
And we're going to be able to track the expansion.
Yes.
And then track the expansion backwards.
Right.
To see when it's
when you will know for a fact.
Oh, my gosh.
And see, this is the cool thing about Astrophysics because it comes with receipts.
You know what I mean?
You cannot bullshit.
This is Cicero Artifon.
What a cool name, Cicero.
We've had Cicero before.
We've had him before.
Well, this is more than one Cicero out there, but I doubt it.
There ain't no true Cicero Artifon.
That's for sure.
Hi, Dr.
Tyson, Dr.
Shauer, Lord, nice.
Cicero Artafon here from the cold lands of Toronto, Canada.
We use these incredibly bright supernovae as standard candles to figure out how far away galaxies are.
But it feels a bit counterintuitive, doesn't it?
How can something so incredibly distant and that happened so long ago act as a reliable measuring tape for the cosmos?
What's the ingenious method that allows us to use these far-off stellar explosions to gauge such immense distances?
That's a a terrific question.
These are the so-called Type 1A supernovae.
You weren't happy with just two types of supernovae were you?
We had to subtype and subtype.
The type 1As are the magical supernovae that give us astronomers a yardstick.
We want to know how far away something is
so that we don't just see how bright it is, but how energetic it is.
We can turn brightness into energy, into physical units.
Right.
And the Type 1As are something that we call standard candles
or equivalently, standard 100-watt light bulbs.
Candles were quite honored that we used them in this reference.
Yes, they did.
It's very classical.
Since they really suck as a light source, they should be honored, but go ahead.
Well, the standard candle was made out of whale blubber.
Whale blubber has certain sizes.
The oil lamps.
Yeah, the oil lamps.
I take it back then because, believe it or not, those actually burn pretty evenly.
Well, if you have a big enough wick.
That was the point.
The beautiful thing about Type 1A supernovas is not that they are really all exactly the same intrinsic luminosity, but...
Because we're able to measure the distances to some galaxies with other tools that we believe in very firmly, especially the Cepheid variable stars and now the so-called tip of the red giant branch stars, we have a few hundred galaxies whose distances we know with great accuracy.
Nearby.
Nearby.
Out to perhaps 50 million light years.
That's nearby.
50 million light years.
Far back, far back.
Let's go to tomorrow.
And we see type 1a supernovas going off there, and we can measure their light curves, their brightness as a function of time, very precisely.
And then we put them on the the same graph and we see that the brighter ones also last longer.
But when we collapse them down
to the same
width, in other words, if we just shrink them digitally,
both in brightness and in width, they all lie right on top of each other.
So they are standardizable
candles.
Standardizable 100 watt light bulbs.
That makes that's crazy.
So the thing we can measure easily is how long they take to fade.
And then we use that, how long they take to fade information to crunch down the light curve onto the standard light curve.
And then we can look at supernovas that are 10 or 20 times further away than the furthest Cepheid.
And that's how we can step way outside our backyard.
So it relies on the nearby calibrations, basically, to trust what the extrapolation is going to be yeah and then you get far enough out to say good grief we thought the hubble constant meant that the universe was always expanding at the same rate everything is cool right it ain't so right we have a change we have a an acceleration in the expansion of the universe Where did that come from?
Who ordered it?
The so-called dark energy?
We have no idea what it is, why it's there, et cetera, et cetera, but it seems to be there.
And that's because of the Type 1A supernova.
Because you know, because of your standardizable
candle system, that it works all the way out to here.
It's just that when you got to that point beyond that, that's when things change.
Well, something had to change because everything else going
from this point forward to us still works.
Everything still works.
The physics is.
physics works but it allows us to implicate the universe and not
standard care that's the point correct yeah that's amazing and to answer the second part of the question um why does the how did the universe figure out to do something like this it turns out to be these wonderful white dwarfs these collapsed objects actually have a maximum possible mass.
They can't get more than about 1.4 times the mass of the sun.
If they do,
then the gravitational forces within cannot be resisted by any pressure force without.
And so there is a magic number.
They actually calibrate themselves for you.
There you go.
That's amazing.
Oh my God, size is so crazy.
No, no, think about it.
Because if the white dwarf would
blow up at different masses,
you don't know what you're looking at.
But everybody's blowing up at the same mass.
It's just a little more complicated than that, but here's the one caveat.
I was proud for a second.
Because you can have two white dwarfs, a binary white dwarf, merge.
Ah.
And then you can be anywhere between 1.4 and 2.8 times the mass.
That's a dot, yeah.
So that would still count as a 1A supernova.
That would still count as a 1A.
And that's why you have...
brighter ones and fainter ones and shorter decay times and longer decay times because you have the little guys at the 1.4 and the bright, bright guys at 2.8.
Okay.
Okay.
And we've learned how to calibrate for that
little extra confidence.
That's happened like since I've been in graduate school.
I don't think we knew that back in my day.
Nope.
Right.
Nope.
Now, so my little contribution to this.
Go ahead.
I am last author on a paper.
Okay.
Last but not least.
Last author on a paper.
The first author was Brian Schmidt.
Okay.
Okay.
Nobel Prize winner.
Nobel Prize winner for
co-discovering the dark energy
with supernova type 1A.
I'm on one of his supernova papers where, very proud of this,
it is a supernova whose light curve
does not fit.
the light curve of other supernova that it's supposed to until you invoke the expanding universe time dilation on its light curve.
There you go.
And then when you d
then when you mathematically remove the time dilation of the light curve, it falls right back on on Q.
Super cool.
So you get its distance and its speed with which it's receding.
And that
rate stretches out the light curve.
And so it was the first paper to demonstrate that.
And now it's a routine correction that you make.
So
let me just see if I got this right.
The stretching of space
is really what makes the difference.
Yes, and the stretching of space also stretches the time
the time frame.
That's correct.
Wow, you smart, man.
Oh, there's 15 other authors on it.
But they were all brave.
Because the first time you publish something wildly different from what anyone else has ever seen, there's always this little nagging voice in the back of your mind.
Did I screw up somewhere?
Am I going to be a laugh?
Is this interesting result resulted in me screwing up?
Right, right.
Because if it matched other results, you all couldn't have screwed up in the same way.
Right.
Right, right.
So just to be clear about the timing.
So
if you are receding
and you're sending one pulse per second, let's say, but you're receding, the next pulse will not get to you after a second.
It's a little longer.
Exactly.
Because you're now farther than when you sent the first pulse.
And so
that in a timed light curve will stretch out the light curve.
That's all.
No.
And so this got corrected for.
And there's...
I mean, you say it like it's nothing, but I mean, that's pretty elegant
if you think about it.
I mean, and he went on and got a bunch of these and got the Nobel Prize.
And that was it.
Deservedly so.
I didn't get an invitation to the Nobel Prize.
Oh, wow.
Listen, it's in the mail.
Michael, I think we have to quit it there.
Wow, that was great, man.
I mean, you're such a good talker.
We didn't get to as many questions as we might have.
Sorry about that.
But they were good questions.
Yeah, they were great questions and great, great answers.
And I learned a lot.
So, well, this is this is, I don't, I can,
I can, I can actually, uh, tonight, uh, when I take my Oedible, I can think about all of this.
I can think about all of this and really just like marinate.
Just before you do, though, I want you to check whether T-Corbore has exploded.
Oh, I'll do that before.
You can look out your window because
first I'll check my neutrino detector.
Otherwise, you may see three or four T-Corpores when you look out the window.
All right.
Thanks.
Friend and colleague, Michael Shara.
Great pleasure.
Thank you.
Chuck, always.
Please have you, man.
Always a pleasure.
All right.
This has been yet another episode of Stark Talk Cosmic Queries, the Exploding Stars Edition.
Yeah.
Neil deGrasse Tyson, bidding you, as always, to keep looking up.