What in the world is metallic hydrogen? What does it even mean? Where does it exist in nature, and can we make it in the lab? I discuss these questions and more in today’s Ask a Spaceman!

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Keep those questions about space, science, astronomy, astrophysics, physics, and cosmology coming to #AskASpaceman for COMPLETE KNOWLEDGE OF TIME AND SPACE!

Big thanks to my top Patreon supporters this month: Justin G., Matthew K., Kevin O., Justin R., Chris C., Helge B., Tim R., Nick T., Branea I., Lars H., Timothy G., Ray S., John F., James L., Anilavadhanula, Mark R., David B., and Silvan W.!

Music by Jason Grady and Nick Bain. Thanks to WCBE Radio for hosting the recording session, Greg Mobius for producing, and Cathy Rinella for editing.

Hosted by Paul M. Sutter, astrophysicist at The Ohio State University, Chief Scientist at COSI Science Center, and the one and only Agent to the Stars (http://www.pmsutter.com).

EPISODE TRANSCRIPTION (AUTO-GENERATED)

You know what time it is. It's time for Ask a Spaceman. I'm your host, Paul Sutter. You've got questions and I've got answers. You go online to Twitter or Facebook, use the hashtag AskASpaceman, and I will take those questions and I will answer them eventually. You can also email me at AskASpaceman at gmail.com or visit the website AskASpaceman.com, kind of convenient, or visit my YouTube channel, youtube.com slash PaulMSutter.com. You can ask questions all over the place. We have one simple goal with this show, complete knowledge of time and space. And on the road to complete knowledge of time and space, we have today's questions. We have Tom S. and at Abguntha via email and Twitter, respectively, asking about metallic hydrogen with several question marks after that. We have Andres Del C via YouTube. Could you please talk more about liquid metallic hydrogen? And we have Colin E via email. What's inside Jupiter and how did it get there? Metallic hydrogen. Okay, I need to take a few steps back.

Let's talk about phases of matter. Good old phases of matter. We're used to thinking of things very simply. Solid, liquid, gas. And transforming from one phase to another is very easy. Like take water. Take some solid water, aka ice, add some heat to it, add some temperature, increase its temperature, and it becomes a liquid. Then add some more heat and it becomes a gas. Okay, so that's pretty easy. If I want to take a material and change its phase from one thing to another, I just need to add heat or subtract heat. But pressure also gets to play in the phase changing game. So let's take room temperature water, which is a liquid, and stick it in a vacuum. Put it up in space. Put it in a vacuum jar and suck out all the air. What happens? It boils. It becomes a gas. So same exact temperature. Same exact room temperature water. Water that would be neither pleasant nor disgusting to drink. Just kind of meh. In a vacuum, it becomes a gas. And so we need to play both the heat game and the pressure game in order to change phases.

And we map this out using what we call phase diagrams. These phase diagrams say, okay, if I'm at this temperature and that pressure, I will have this state of matter. And every element or molecule or material gets its own unique phase diagram. So I'm Hydrogen will have a different one than hydrogen combined with oxygen to make water. And that will be completely different than oxygen by itself. And from carbon and lithium, everyone has its own phase diagram. Everyone has its own response. to temperature and pressure. And the phases in a diagram are like the countries, are like countries on a map, where there's boundary lines. And if you have this temperature and pressure combination, then you're within this boundary, you're within fluid land, and you obey the laws of the physics of fluids. But if you have another combination of temperature and pressure, you're in a different section of the map. You're in Gazistan. And you have to obey the ideal gas laws. And usually they're very strict boundaries where you can travel along this diagram just like you travel in a country and then you hit a border and you go through border control and then boom, you're in a new country with a new set of laws.

And that's what we see as changing faces. You're a liquid, you're a liquid, you're a liquid. Boom, you hit a border in temperature or in pressure and you keep adding heat or you keep adding pressure or keep removing heat, keep lowering the pressure or whatever. Then boom, you cross that border and now you're a gas. But there are some interesting places in these maps, in these phase diagrams. There are no man's lands. There are places that don't follow the usual rules of solid, of liquid, of gas. And it's usually when you go outside our normal everyday experience that these strange things happen to these materials. I think these strange things are properties of the materials themselves, but we only get to see these properties under extreme conditions. We don't normally see how water might behave or hydrogen might behave in this weird way until we really crank up the temperature, really lower the pressure. Then interesting things get to happen. It's like international waters. Like if you really crank up the temperature and pressure, these definitions of solid, of liquid, of gas get really, really fuzzy.

And if you're out in international waters, well, what rules apply to you? You're not really in any country. So who do you obey? How do you govern yourself? An example of this is what's called the critical point when it comes to water. There's a certain temperature and pressure that if you increase the temperature and increase the pressure beyond a certain point, water is no longer a liquid and it's no longer a gas and it's definitely not a solid. It's its own thing. It's its weird mix of liquid and gas properties. It kind of has some properties of gas and some properties of liquid, but But then some properties are missing, so it's its own thing. And if you only get there by cranking up the pressure and temperature past a certain point, what's called the critical point. Hydrogen has its own phase diagram. We usually don't get to experience almost all of that phase diagram. Under normal conditions here on the surface of the earth, with everyday temperatures and everyday pressures, it's almost always a gas.

If you find some hydrogen and it's by itself, it's a gas. It's just going to be a gas. You can heat it down to zero Celsius or heat it up to 100 Celsius. Nope, still a gas. Very low pressure, very high pressure, still a gas. If you cool it way down to 33 Kelvin, that's 33 degrees above absolute zero, it does become a liquid. And if you cool it down below 14 Kelvin, so anything less than 14 degrees above absolute zero, it becomes a solid. So you can make liquid heat hydrogen and you can make solid hydrogen. It just has to be really, really cold. But that's at typical normal everyday pressure. So if you keep the everyday earthly pressure, one atmosphere, say, and you lower the temperature, then you get to liquid and a solid. If you crank the pressure up, you can raise the temperature and you can actually get back a hydrogen solid. So there is solid hydrogen at high temperature, but that's only at very, very high pressure. And hydrogen has these particular properties because hydrogen doesn't like to be by itself.

Hydrogen is just a single proton with a single electron in a shell around it. That's it. That's all it takes to make a hydrogen atom. And a single proton with a single electron is like the most eligible bachelor or bachelorette in the elemental world. It'll just hook up with anybody. Doesn't care. Usually, it just pairs up with itself. So we usually get hydrogen as twins. Hydrogen, in our normal experience, is diatomic. It merges with itself. It combines with itself to make molecular hydrogen that is much more stable, much less reactive, just likes to hang out by itself or with itself because it's a twin. All right. And so when you encounter hydrogen gas, you're actually seeing diatomic hydrogen gas. Hydrogen molecules are paired up together. When you cool it down to make a liquid, that's diatomic hydrogen as a liquid. Freeze it so it's solid when you're below 14 Kelvin, and that's diatomic hydrogen frozen solid. But if we're devious enough, if we're crazy enough... We can split those bonds.

We can break diatomic hydrogen apart. And we can get monatomic hydrogen. All right, it sounded, it looked cooler when I wrote it down in my notes, and it didn't sound that great, but we're just going to roll with it. We can play some games where we can split that hydrogen apart. What does it take? It takes Patreon. Go to patreon.com slash pmsutter to learn how you can support the show and all the education outreach activities I do. There's way more details on the Patreon page itself. I can't thank you enough for all of your generous contributions for this show, but I'm going to try again. Thank you so much. That's patreon.com slash pmsutter. What does it really take to split hydrogen apart so we can see the bare elemental hydrogen? It takes incredible temperatures and or incredible pressures. And if you just take a hydrogen gas and you really heat it up and you keep the pressure low, you're going to get a plasma where the protons and the electrons separate from each other and you just get a thin, hot, soupy mix of protons and electrons.

Like the sun, the interior of the sun is this hot, soupy mix of protons and electrons. It's a plasma of hydrogen. What if... You increase the temperature and you increase the pressure. What if you did both? So you get a plasma, a fourth state of matter, if you increase the temperature but you let the pressure go. What if you have both high pressure and high temperature? Well, past a certain combination of temperature and pressure, the bonds between the paired hydrogen are forced apart and and you get individual hydrogen atoms, aka protons, and they float around. What do individual protons floating around look like? It looks like a liquid. But this is a very different kind of liquid than the cold temperature liquid hydrogen. That one at 33 Kelvin was still diatomic. It was still two hydrogens glued together, paired up, fluiding around, doing whatever a fluid does. This is a very different beast because the bonds have been broken. Because the hydrogen has been ripped apart, now it's just single protons and single electrons floating around.

That's going to behave differently than the low temperature version, we think. I'm saying we think because this is largely theoretical. I'll get to the experiments in a bit. You need, in order to make this happen, this weird state of hydrogen, you need at least one million times sea level air pressure and preferably, you know, three or four million times sea level air pressure. And you need at least around a thousand Kelvin to do the trick as well. We think hydrogen will behave this way because we understand the chemistry, because we understand electrostatic forces, because we understand quantum mechanics. We can predict that this is how hydrogen ought to behave at high temperature and high pressure. Let me talk about this some more before I get to the experiments. The best word I can use to describe the state of hydrogen at extreme pressures and extreme temperatures is weird. Not only are the protons separated from each other... because of the extreme pressures, but the electrons are forced out of their shells and they also float around.

So you get a soup of protons and electrons like the more familiar plasma, but with insane pressures. And it's so different from a plasma that we give it a new name. We call it metallic hydrogen. Why metallic? Well, think of a metal. How would you define a metal? Is it hard, shiny, a good electrical conductor, probably dense, doesn't have to be dense, but typically dense? Metals, and most elements, by the way, are metals, have these properties because the atoms or the molecules that make up the metal, they link up, they link together to form a lattice. So their electron shells overlap, right? They link together, and each atom will have a few electrons left over. So they'll use some electrons to form the bonds, the linkages between them, and then there'll be some electrons left over that just float around and just hang out. So you get a lattice, a structure of ions, that's the atoms that are linking up together, and then these are embedded in a sea of free-floating electrons. And it's these free-floating electrons that give the metal most of its properties.

That's what makes it shiny, that's what makes them good electrical conductors. And if you melt down a metal, you get a liquid metal. You can take gold and melt it down and it's still gold. It's just the liquid phase of gold. And it still has all the essential properties, except for being hard. But it has a lot of the essential properties. There's still these linkups of the gold ions. There's still free-floating electrons. So you can have liquid metals. The concept of a liquid metal isn't that crazy. And it's the properties of those free-floating electrons that make a metal a metal. So here we have hydrogen at high temperature and high pressure. And hey, look at that. The electrons are floating around. That's a metal. It's probably shiny. It's probably a good electrical conductor. It's probably pretty dense. That's not so bad. All right. Metallic hydrogen. It turns out if you take hydrogen and subject it to high temperatures and pressures, it forces apart the atomic bonds. It forces apart the electric bonds and you get a new soupy thing that kind of sort of looks like a metal.

It's not the only element that does this. There are things like carbon that when you subject it to high temperatures and high pressures may not normally be a metal will start acting like a metal. And so that's not really the crazy part. Here's the crazy part. A normal medal, like a bar of gold, that you can donate to patreon.com slash bmsutter. When you pick it up and say you squeeze that bar of gold, you pick up that bar of gold and you want to squeeze it. It resists you. All right. It's pretty tough. It doesn't like being squeezed. What is resisting you? Well, it's those it's those ions. It's the atoms and molecules that are all linked together that have formed this lattice. They don't like being squeezed any more than they already are. So they share electrons so they can link up. But that's as close as they're going to get. And so you can try squeezing on it, but you're pressing, you're trying to overcome the electrostatic bonds, the electrostatic repulsion between these ions. They just don't want to get any closer to you.

And it's just the electromagnetic force that's supporting that pressure where you try to squeeze, but it's going to say, nope. I've got electrostatic. I am literally repulsed by my neighbor, and I'm kind of linked up to them against my will, but here I am, and there's no way you're going to get me to squeeze any tighter. Metallic hydrogen does not do that. It's a liquid. It's a soup. It is also not going to want to be pressed together, but... There's no latticework. There's the free-floating electrons, which make it behave like a metal, but there's no latticework of ions because the ion of hydrogen is just a proton. It's just a single proton. It's got nothing left to give. It's not going to link up. It's not going to share electron shells in orbitals and blah, blah, blah to form a lattice. It's just a proton, folks. It's not going to make that latticework. So it's not electrostatic. It's not the electromagnetic force that's preventing you from squeezing metallic hydrogen tighter together.

Instead, it's degeneracy pressure. It's quantum mechanics, folks. It's the good stuff. degeneracy pressure, normally you only encounter it in discussions of, say, white dwarves or neutron stars. You can only put so many electrons in a box. Say you fill up a box with electrons. They have all the same charge, so they're going to repel. They're not going to want to get closer together. That's electrostatic repulsion. You can squeeze on them and make them get closer together. And you can do a pretty good job. So if you take a bar of gold, you can put it in anvil or whatever. You can squeeze it. You can make them get closer together whether they like it or not. You can overcome electrostatic repulsion. But then you'll hit a limit. You'll hit a limit because no two electrons can share what's called the same quantum state. They cannot be in the same place at the same time. They just can't. So even if you're able to overwhelm the electrostatic force, you're going to hit a wall, and that wall is degeneracy pressure.

Here's another way to think about it and why it's a quantum mechanical thing. And this way to think about it is from the Heisenberg uncertainty principle. If you take, say, a couple electrons and you squeeze them really close together, what are you doing? You're pinning down their position. You're saying, you're going to be right here, not over there. You're going to be right here, right between my fingers that are squeezing really, really, really, really tight. So that is reducing the uncertainty in the position. They can't escape. They're being squeezed down. But if in the Heisenberg uncertainty principle, if you reduce the uncertainty in position, you increase, you enhance the uncertainty in momentum. Momentum is velocity. So it's the more you try to squeeze two electrons together, the more they're going to vibrate. the more they're going to buzz. And that buzzing, that vibration, that momentum is like a pressure. You know, they're like, imagine trying to take two bees in a small metal box and you're making that box smaller and smaller and smaller.

You're saying, no bees, you're going to be right here in this tiny little box. But they're going to go nuts. They're going to go buzz, buzz, buzz, and they're going to bounce against the walls of that little container, especially as you're trying to make it smaller and smaller. And that will resist them. you trying to push it together that will resist you trying to make it smaller. That is a pressure. And that is degeneracy pressure. And that is a pure quantum mechanical thing. This isn't the electromagnetic force supporting liquid metallic hydrogen against further collapse. It's quantum mechanics. That's what makes metallic hydrogen weird. It's a liquid, it's a metal, and it's dominated by quantum mechanical forces. That's the secret sauce. That's the specialness in liquid metallic hydrogen. To make liquid metallic hydrogen, you need pressure and heat. You need them both. Where can you get? The sun is pretty hot and there's a lot of pressure, but there's also a raging nuclear fire in the core, so it's a little bit crazy there.

So it turns out the material in the sun, the hydrogen in the sun, just turns into a plasma. Earth's core is very hot. And it's under a lot of pressure, but there ain't a lot of hydrogen there. So good luck with that. What about the gas giants? Yeah, yeah, yeah, yeah. Jupiter and Saturn are gas giant planets full of hydrogen, also helium. So you have all the right ingredients in Jupiter and Saturn. You have hydrogen, which if you're going to make liquid metallic hydrogen, good to have some hydrogen on hand. You have hydrogen, you have high pressure because, you know, just, you know, go down under the cloud tops and the deeper you go, the more stuff is going to be on top of you. So that's naturally going to provide a lot of pressure. What's really going on inside of Jupiter? Well, we honestly don't fully know. I mean, we haven't stuck a lot of probes deep inside Jupiter, especially thousands of kilometers where we think things might start getting really interesting. We know the cloud tops.

We know surface activity. We know about the atmosphere just underneath it. That's from observations with different wavelengths of light that can penetrate the very topmost layers. But also by looking at the formation of storms and cloud patterns that put certain requirements on what's happening just underneath it. We can use the strength of the magnetic field around Jupiter to understand what's happening mixing up deep in its core. We can use variations in the gravity as we orbit spacecraft around it. And we can use simulations and computer modeling and compare with observations and figure out what's going on inside. Mostly... Jupiter is hydrogen with helium and a few other things. And getting that higher pressure, again, we don't know for sure what's happening inside Jupiter, but slowly over time, we're getting a better picture, especially with instruments like the Juno spacecraft, which is in orbit around Jupiter right now, unless you're listening to the show deep into the future, in which case Juno was a spacecraft that orbited Jupiter.

Higher pressure is easy. Just go deeper. There's more crushing weight of atmosphere on top of you. Eventually, actually, the hydrogen gas gives way to a diatomic hydrogen fluid that passes critical point. So it's not quite a fluid or a gas, just like water passes critical point, blah, blah, blah. So there's like a thin transparent layer of hydrogen fluid slash gas. And then you go even deeper. But you need the temperature too. And how do you get hot inside a gas giant? It turns out it's this really interesting mechanism called the Kelvin-Helmholtz mechanism. Not to be confused with the Kelvin-Helmholtz instability, which is another show. Feel free to ask about that. This is the Kelvin-Helmholtz mechanism. Check it out. You have a ball of gas. Could be a planet, whatever. It's a ball of gas. Its surface is exposed to space. So it's going to radiate heat because that's what things exposed to space do. It'll glow a little bit. Radiate heat. What does a gas that radiate heat does? It cools off.

What does a gas that cools off does? It compresses. It gets smaller. So... You have the outer layer of the planet cooling off, which is going to make it compress. That squeezes the core. What does the gas that gets squeezed do? Doesn't happen? Whatever. It heats up. The core heats up. That makes the surface hotter. What does the hot surface do? It radiates. What does that radiation do? It cools off the surface. What does the cooling surface do? It squeezes the core. What does the squeezing core do? It heats up. What does the heat do? It's a cycle. It's a mechanism. It keeps the interiors of giant planets warm. This is what prevented them. Otherwise, they would have cooled off a long time ago. But this act of radiating heat, compressing, can make the cores very, very hot. There's other possible mechanisms of heating the interior of Jupiter. You can have helium rain form and falls through the metallic hydrogen. Spoiler alert, there's metallic hydrogen in Jupiter. There's friction here and that can generate heat too.

We don't know what is the most important mechanism, but there's a couple. How did these elements get inside of Jupiter? They were born with it. Our solar system was three-quarters hydrogen, one-quarter helium, and a small percentage of other stuff. The pre-solar disk, that's what it was made of because that's what basically everything in the universe is made of. And the gas giants got to, and the sun, got to retain a memory. Here on Earth, we lost our hydrogen, we lost our helium, we just have the heavier stuff. But the outer planets past where it's too cold to obliterate by radiation any ices that might form, you get to retain a memory. You get to keep that image, kind of that window into the early solar system. And that's why studying Jupiter is so important. It is a window into the very early solar system. It's a picture of what our pre-solar disk looked like before we got here. But that's another show. So there, in the core, or in not quite the core, we think the core of Jupiter might be solid, but there is a very thick layer.

Most of the volume of Jupiter actually has the right conditions, the right temperatures, and the right pressures to make metallic hydrogen. Liquid metallic hydrogen. So most of Jupiter, we call it gas giant. Most of it is actually liquid. Most of it is actually liquid with an atmosphere, a gaseous atmosphere on top of it. You dive down deep enough, you will encounter this strange state of matter. That is a liquid. That is a metal. That is supported by quantum mechanical forces. How crazy is that? Usually you think of these weird quantum mechanical effects and you have to go to a white dwarf or a neutron star. No, you can just go in our backyard. Right there. Go in your backyard, look up, find Jupiter, find Saturn. You're looking at a giant ball of liquid metallic hydrogen. How awesome is that? That is significantly awesome. Before I go, I do want to talk about the experiments that have been done. We've been trying to make liquid metallic hydrogen in the lab, or at least some form of metallic hydrogen.

You can also have solid metallic hydrogen. Every few years, there's claims of making it in the laboratory, most recently at the end of 2016, using a diamond anvil, which is a great band name, by the way. Feel free to use that if you're trying to cook up a band name. Diamond anvil creates an enormous amount of pressure, which is what you need to make metallic hydrogen. They thought the latest experiment, the end of 2016, may have been a lock. In fact, in the abstract of the paper where they announced it, they said, yes, we totally made metallic hydrogen. It was disputed almost immediately. And the sample of metallic hydrogen survives. It turns out metallic hydrogen, for various reasons, is what's called metastable, which means if you make it and you don't bother it, it will actually hang around for a while. But apparently they bothered it and then it disappeared and they haven't been able to make it since. And so that is still up in the air of whether metallic hydrogen has been created in the laboratory.

Right now, the only place where we're pretty sure metallic hydrogen exists is in Jupiter and in Saturn. But we're not 100% sure. Remember, this is a theoretical state of matter based on our understanding of the laws of physics and our understanding of chemistry. Maybe wrong, probably not. There's probably liquid metallic hydrogen in Jupiter and Saturn. More measurements by the Juno probe and... What's left of the Cassini probe after it plunged into Saturn. The data we're still analyzing, trying to understand that, you know, what is the character of this very exotic, very strange and yet kind of normal. Hydrogen had this superpower in it the whole time. You just needed to subject it to extreme stress in order to bring it out like normal superpowers. Before I go, two quick announcements. Again, Space Radio is live where you can talk to me on the radio and ask me questions and I'll answer right away. Spaceradioshow.com. We record every Thursday at 4 p.m. Eastern. Call 888-581-0708 to talk to me.

And also astrotouring.com. Fraser Cain and I are at it again. We are going on a Caribbean cruise to experience some beautiful dark skies, to experience the Kennedy Space Center, to experience some mind ruins together. And we want to do it with you. Not you, you. Yes, you. astrotouring.com. Sign up, because it'll be fun. Thank you so much to my Patreon contributors, especially Justin G., Matthew K., Kevin O., Justin R., Chris C., and Helga B. It is your contributions that keep this show going and growing, and all my education and outreach activities. I'm eternally grateful. Thanks to Tom S. at Abguntha, Andres Del C, and Colin E. for the questions for today's episode. You can ask more questions by following me on Twitter and Facebook at Paul Matt Sutter using the hashtag Ask a Spaceman. Go into AskASpaceman.com. Go into YouTube.com slash Paul M. Sutter. Whatever you do, just get me questions, and I will see you next time for more Complete Knowledge of Time and Space.

How does one become an astrophysicist? What are the challenges and rewards of that kind of career? Are there even any jobs? I discuss these questions and more in today’s Ask a Spaceman!

Support the show: http://www.patreon.com/pmsutter

All episodes: http://www.AskASpaceman.com

Follow on Twitter: http://www.twitter.com/PaulMattSutter

Like on Facebook: http://www.facebook.com/PaulMattSutter

Watch on YouTube: http://www.youtube.com/c/PaulMattSutter

Go on an adventure: http://www.AstroTouring.com/

Keep those questions about space, science, astronomy, astrophysics, physics, and cosmology coming to #AskASpaceman for COMPLETE KNOWLEDGE OF TIME AND SPACE!

Big thanks to my top Patreon supporters this month: Justin G., Matthew K., Kevin O., Justin R., Chris C., Helge B., Tim R., Nick T., Branea I., Lars H., Timothy G., Ray S., John F., James L., Anilavadhanula, Mark R., David B., and Silvan W.!

Music by Jason Grady and Nick Bain. Thanks to WCBE Radio for hosting the recording session, Greg Mobius for producing, and Cathy Rinella for editing.

Hosted by Paul M. Sutter, astrophysicist at The Ohio State University, Chief Scientist at COSI Science Center, and the one and only Agent to the Stars (http://www.pmsutter.com).

EPISODE TRANSCRIPTION (AUTO-GENERATED)

you know what time it is it's time for ask a spaceman i'm your host paul sutter you've got questions and i've got answers you know how the show works but let's ask the question and get the answer again you go online to twitter or facebook use the hashtag ask a spaceman and Fire those questions away, and I will catch them. I will catch them with my space internet powers, and I will put them in a file, and then I will peruse the file, and I'll pick ones to answer on this show. It is that simple. You can also email me directly at askaspaceman at gmail.com or visit... Ask a spaceman.com. That's the website. There's all the show notes, links to all the episodes. You can start to see if I've already answered the question. Maybe before you ask, you know, all sorts of stuff. You also, you can also go to youtube.com slash Paul M Sutter, where there's all sorts. Thank you so much for watching. At 92 Rufino asked, what does it take to be an astrophysicist? And we have Vicky K via email asking, what kinds of non-academic jobs are available in astronomy or physics? And how do I become a spaceman and or space woman? excellent excellent question i get these questions a lot especially from kids so if you you it may be too late for you to become an astrophysicist you're already set in your career and you're already living a a healthy and happy and productive life uh but maybe you have kids or maybe you're maybe you're not quite at that stage where you're set in your career and you're wondering about physics and astronomy and usually when kids are asking me this question they typically tend to be middle schoolers and high schoolers and they're worried.

They're stressed out. We talk so much to middle schoolers and high schoolers about careers and options and setting your path in life that I think they tend to get stressed out. They're worried about making the right choices, about picking the right classes, about extracurricular that and club this and what do I need to do? What's the best choice for college, et cetera, et cetera. I get it. I get it. If you're young and you know what you want in life, you don't want to screw it up. You want to hit every right note to maximize your chances of having your dream job. So to ease those fears, so when I get those questions, I tell my own story. I tell my own story of how I became an astrophysicist, and I think that might ease some of the fears. Or if you have a youngster in your life that you know that is interested in a career in physics and astronomy, you know what? The path might be a little bit different than you expect. And the number one thing I say, and this is 100% true, I did not take a single physics class in high school.

I am not joking. My high school had two options. You could either take a track of physics and chemistry, or you could take a track of computer science. And I picked computer science. And I was one of like two kids that did it. But there we were taking computer science when everyone else was taking physics and chemistry. And I didn't take any physics, any chemistry in high school, which is interesting because I had always loved reading books about science. As a kid, I loved astronomy and dinosaurs. And as I got up in the middle school and high school, I liked more technical subjects. So I was reading books about astronomy and physics and history and biology and all that good stuff. And two books I remember in particular, one is Elegant Universe by Brian Greene and And the other is Godel Escher Bach by Douglas Hofstetter, both very influential books into my life, my upbringing, and my current mental state. And I did have a telescope that I barely knew how to use. I got it for my birthday when I was 12.

12 or something. And, you know, I could use I could I could look at the planets. I figured I was able to pick out some nebula and some globular clusters and things like that. But I didn't I didn't bust it out a lot. But thinking back, I really don't know. Why I didn't take the physics track. I was also a computer geek, to be fair. I do love computers and programming and all that kind of stuff. And so it was natural for me to pick computer science. And so I went into computer science in college. I wasn't even on a science track, a physical science track. And... I really don't know why. I never took an interest in it. I never thought it was for me. Maybe I just never realized that being a scientist was an actual job. It was just something that other people always did. Maybe there were feelings of inadequacy. They're like, there's no way I could do something like that. Like, oh, this person's figuring out string theory. This person's figuring out dark energy. There's no way I could do that.

I'll just have to sit in the back and program some computers. And computer science was nice. And if you're a computer scientist, I'm very happy for you. But it wasn't really fulfilling for me. The kinds of problems we were using to develop our skills just weren't very intellectually stimulating for me. And the third year of college, I took an elective in astronomy. And I still remember the teacher, Professor John Poling. And I barely remember the content of the class. It was an astronomy course for... Like engineering majors. So it's slightly more technical. There was a decent amount of math involved and some jargon. But it was an overview of astronomy. And something about the class just clicked. And I remember having conversations with Dr. Bolling. And in the first... three weeks of the class so this is like before we even had our first test i'm like well i'm really digging this like i had taken physics classes in my freshman year and sophomore year and they were just physics class i didn't really think much of it but it was in this astronomy class that something really was pulling at me and in three weeks into the semester no joke i woke up one morning and i this thought popped into my brain i just woke up and said i'm gonna be a physicist Boom.

Absolutely crystal clear thought. And by the end of the week, I'd switch majors and I had to drop half my classes because they were computer science classes and no longer applicable to my new newly declared major. I was going to be a physicist. I didn't know if I was going to be an astrophysicist or a high energy theorist or, you know, or a whatever. I just knew I wanted to push in this direction. This direction made more sense to me for reasons that I can't really describe yet. The very next semester, I regretted my decision because that's when I started taking the serious physics classes, the physics classes for physicists, the physics classes designed to make you question your life choices, right? that are deliberately hard. And it was just a course on classical mechanics, rotational motion, drag, fancier things like Hamiltonian formulation of mechanics. And it was really tough. I mean, there were tears. I'm honest enough to admit I cried during that class. It was rough going, but it was clicking.

It was fitting. It was tough, but I kind of liked it. I never got 100% comfortable with the mathematics in pretty much my entire career. I don't consider myself an exceptional mathematician. I at least had ceasefire agreements with the mathematics so we could make progress together. And I started taking more classes. The more classes I took, the more I enjoyed it. I started taking classes on special relativity and general relativity and thermodynamics, statistical mechanics, all the guts that goes into doing lab classes and recreating famous experiments. And I was having a really good time. It was mind-blowingly tough, but I liked it. And as my bachelor's in physics was approaching, I was approaching graduation. Now what? And I decided to aim for grad school. Why? To be a professor, to be a researcher. I don't know. It just seemed like a good idea at a time. I think the thoughts I was having was, I'm feeling good. I'm liking this. Let's see how far I can push. Then I get into grad school at the University of Illinois.

And... When you first show up for grad school, you know, you have to write some essays like, I've always wanted to be a physicist. And it's really special to me. And I'm really interested in insert research topic here because of this childhood experience there, blah, blah, blah. So I wrote some essay. I don't even remember. It was probably horrible. But I got in. It was good enough, I guess. I got in. I didn't have a focus. Like, is it going to be cosmology? Is it going to be astronomical surveys? Is it going to be particle physics? It took me a few months to decide. But eventually I settled on astrophysics and cosmology. I found a good advisor and we had a really good time. And when kids ask me how long I went to school, how long did you go to school to become an astrophysicist? The answer is 11 years. And they usually lose their junk. I mean, it's just of all the space facts I've related to them, nothing blows their minds more than telling them, yes, I went to school for 11 years after high school.

But I have to explain because that sounds like a big number. It is a big number. It's a good chunk of my life. It took me five years to get my bachelor's and then six more to get the Ph.D. But in graduate school, in that six years of graduate school, you're only in classes for about two years. And this changes school to school. You're only in classes for about two years. And then the rest is basically a job. You're a trainee under a mentor, your graduate advisor, who's guiding you through a research project and teaching you how to become an independent researcher. And that's much more like a job. Like, you know, here's the list of things we got to do. Let's let's get to it. And then you have weekly meetings with your boss and you have colleagues and you have reports to write all the usual stuff. So it's much more like a job than it is school. And that advisor relationship is key. You pick your advisor in the first or second year of grad school, and it's basically your science parent, your science mom, your science dad, for half a decade.

For five, six, in the experimental physics, this can go to seven or eight years. Theory tends to be a little bit shorter, more like four or five. And It's like so important that you get the bones of your education in your classes. You're going to learn the basics of physics that every physicist needs to know. But it's up to your mentor, your advisor, to bring you up to speed in the discipline you choose because you're not going to learn about the latest in astrophysics research forever. from a class because it's changing all the time. It's changing literally every single day. And so it's up to the advisor to bring you up to speed and show you how to make advances in the field, show you how to become a researcher, how to write papers, how to coordinate with collaborators, how to present at conferences, how to ask intelligent questions, all the guts that go into being a functional member of the academic community. So you have the bones in your classes and you get the guts from your advisor.

And that's where the magic happens. That's where you're transformed into a scientist. It's not in your classes. It's not by getting the bachelor's. It's not by your first couple years of graduate school. It's not the degree itself. It's not the PhD itself. That's like the certification. That's the stamp. The transformation to becoming a scientist happens under the guidance of your advisor. And the coolest thing to me, something that seriously blew my mind, is that your advisor doesn't know the answers. When you pick a problem to work on, Usually your advisor will have say, OK, you know, here's a few things that I'm interested in. You know, pick one of them. That's going to be your focus. That's going to be your specialty. So you work on this together. You pick your dissertation topic together. And it's an intersection of your advisor's interests and your own interests. And your advisor doesn't know what the result is going to be. I remember multiple times and the first time this happened, it really blew me away.

When I would develop some new method or get some preliminary result, you know, I'd be working for a couple of weeks and I did computational astrophysics for my PhD. I run some simulation. I get some result like, OK. And then, you know, I have my meeting with the advisor, Paul Ricker, by the way. At University of Illinois. And, you know, I had to figure it out on my own. And then we'd have the meeting. And then I would have to tell my advisor how I figured it out and what the implications might be. And he would start asking me questions like, well, how did you do this? Well, how do you figure this out? I'm like, wait a minute. Don't you know? Oh, no, he doesn't. Because this is brand new stuff. Nobody's done this before. And the two of us, first me, I'm the first one to ever do it. And then my advisor is the second person on the planet to know about this fact or this insight or this method. And that blew my mind because I thought my advisor was most likely the smartest human being in the world.

And I still think that might be true. And he was light years ahead of me in knowledge. But we were pushing on this problem together as partners, as co-workers, as colleagues. And it was a very, very different relationship where he went from being Professor Ricker or Dr. Ricker to just Paul. Actually, there was a joke, North Pole and South Pole. But it was a very, very strange transition over the course of those six years. And I don't think that kind of relationship happens a lot in other lines of work. It's something very, very special in the sciences. It's a tradition that we've had since forever. since there's been a sciences. You can trace back your academic lineage, your advisor's advisor, your advisor's grand advisor, on and on and on. And this is how science is done. This is where scientists are trained in a very personal, very long-term relationship with an advisor. It doesn't really happen in the classes. It happens in that relationship with the advisor. So I wrote my dissertation, got my PhD.

And remember, when I went into grad school, I didn't exactly have a long-term plan. But as my PhD was approaching, OK, now what? OK, I'll give a crack at being a researcher. And that means getting a postdoc position, what's called a postdoctoral research position. These are temporary jobs used to see if you're really good enough, if you're as good as what you say you are, where you fly out from the nest of your advisor. You try to fly on your own a little bit before you're considered for a long-term faculty position. I had a chance at a job. I took it. It was accepted. And I was on a complete 100% academic research track until about two and a half years ago when I started Ask a Spaceman, this show that you're listening to. I started the show on a whim. I'd always been interested in trying it. And I just had a do or die moment. Let's give it a shot. And it changed my life. You've changed my life. And if you thought there was going to be a Patreon pitch, that's not here. It comes later. And I fell in love with outreach.

I fell in love with communication. I fell in love with sharing what I know and what I love about the universe with anyone who would listen and quite a few who don't want to listen, but they're going to hear it anyway. So now I still do research, but I am focused on outreach and communication. And I definitely wasn't trained in any of this. I didn't get a PhD in science communication because that's not a thing. I didn't have high school classes. I was taking computer programming in high school. I'm not trained in any of this. I'm learning as I go. I appreciate your patience over the past few years. This journey that you've gone on with me of I'm training myself to become a better science presenter so I can make science more accessible, more communicable, more There's a joke about diseases in there somewhere better for you so that you can understand the world that I've been immersed in for a really long time. Here's the point of my story. I didn't have a plan. I didn't have a plan and I did all the wrong things.

I made all the wrong choices to prepare myself with where I am right now. So looking back, I can tell where developing some skills, getting some practice would have been beneficial. But really, I was just winging it. I've been winging it like this feels good and I'm going to push as hard as I can in this direction. Oh, this feels good. I'm going to push as hard as I can in that direction. This feels right. I want to try it. And if it doesn't feel right, I'm not going to push in that direction anymore. And that's been the story of my career, of just my gut instinct, of what I seem to enjoy intersected with what my latent skills are. And then can I develop those skills and refine those skills over the course of my career? That was my experience. I can't tell you. That was a while ago. I got my PhD in 2011, graduated high school back in 2011. as practically ancient history may not be 100% relevant today. So maybe it is the case today that you need to make all the 100% right decisions. You know, if you're 13 years old, you need to start picking your classes, picking your extracurricular activities to get you down the path and that locks you in for the rest of your life.

I really hope that's not true because that's horrible and dystopian because human lives are fluid and imaginative and fun. And, uh, my life has been fluid and imaginative and fun. And I really hope the next generation scientists, uh, have are able to push in the direction of their dreams. That said, I do sit in meetings where we discuss new underground graduate evaluations and, and, uh, applications. I am on a graduate school fellowship committee for the Department of Energy. And so I see the applications I do every year. I get to see the crop of what the high schools and colleges are producing and how they're approaching these careers. So that gives me a little bit of basis that I can offer some recommendations. And these are recommendations in response to specific questions, specific questions like, do I need to take special math or astronomy classes right now, whenever right now is? Not necessarily. Obviously, you should be interested in this subject. But if I compare what I know about physics and astronomy and math and even computer science in what I know now to what I knew in 2011 when I got my PhD or 2011 compared to 2005 or 2005 compared to 2000, I would be frightened.

It seems like an unimaginable amount of stuff. And so I do have people emailing like, please help me. I want to read books. I need to get started. I want a career in astrophysics, so I just have to consume all the knowledge. It comes a little bit at a time, one class at a time. one homework set at a time, one exam at a time, one office hour at a time, one page of a textbook at a time, one conversation at a time, one video at a time, one article at a time. It's a little bit built up over decades where you build the base of knowledge so that you can talk about astronomy, so you can partake in the astronomical or astrophysical or physical conversation. professional world. It doesn't happen instantly, and nobody expects it instantly. Being a physicist is a skill that takes time to develop, a lot of time, maybe more time than most professions, so there's no rush. When I work with an undergrad research assistant, I give them different sets of problems. I have different expectations than when I work with a graduate assistant or when I work with a postdoc, when I'm collaborating with faculty, you know, a professor.

There's different levels. And even professors, maybe this is something outside their normal research line. It's always very fluid. We're always learning. There's a culture of you are always learning. There's also a culture of you are always wrong, which has some negative consequences on your ego, but also liberates you to be open to learning more. There's a culture of you are always learning. You're never done asking questions. Another question I get, is it important to get into a good school? Good is always hard to quantify when it comes to schools. There's various metrics that various organizations use. It's always recommended, of course, but it's not a deal breaker. And when it comes to good, especially when we're talking about graduate education, you're looking at good as usually means a large department, well-funded, good reputation. And your choice of graduate school has much more impact than your choice of undergrad. Nobody cares where I went to undergrad. Basically, nobody cares anymore where I went to grad school.

They care about the work I'm doing right now and the work I've done in the past few years. They don't care where I went to undergrad. But it's a ladder. Like, you know, every step matters for the next step. And then once you've reached that next step, nobody cares about the earlier steps. Quality of education in a graduate institution will be roughly the same. Of course, there are caveats. In fact, if you go to a large research-focused university, you might get a worse education than if you go to a university that only offers, say, bachelor's degrees where they're focused on education. That's because at the research universities, you might be taught by TAs more than the professor, teaching assistants more than the professors. The professors themselves will be more focused on research than actual teaching and education. There may not be a tradition of good pedagogy, of good teaching practices at the university. It varies from school to school, so I can't make general statements. But generally, at an undergrad, you're going to learn about the same stuff as any other place.

So you don't need to fret too much about undergrads. During your undergrad career, I do recommend you try to get at least some research experience. In fact, the National Science Foundation has a program called Research Experience for Undergraduates for exactly this purpose, where you spend a summer somewhere doing some small research projects so you can build up some credibility. So really when it comes – and so that's all I have to say about undergrad is do a good job, impress your teachers, and try to get some undergrad research in. Grad school is a little bit more important and it is better to get into a better school because those schools will have more funding. There's more options for advisors. There's more visitors giving seminars and more opportunities for travel to conferences. Why is this important? Because like all careers, it's all about the connections. You need to do good work. But it really helps to have someone very well-known vouch for you to say, yeah, yeah, this one's the one.

This one's pretty awesome. You should hire them. Those connections are very, very important, especially in a relatively small, relatively tight-knit community like the astrophysics community, like the physics community, like the astronomy community. A letter of recommendation from a rock star in the field is a golden ticket. that can open up many, many, many, many, many, many doors for you. And it's easier to get access to become a student of a rock star in the field because the rock stars in the field tend to be at the larger, better-funded universities. This culture of letter of recommendation writing is very strange indeed. It's very different from what you might experience or expect in the business world. Letters of recommendation, again, these date back for centuries in the scientific world, and it is how you get jobs, really. Because pretty much everyone has roughly the same GPA, like that even matters coming out of grad school, because most of it is research, it's not even your classes.

Just about everyone's done some level of research by the time they get their PhD. You know, they've written a couple papers. They've participated in a large collaboration, maybe. They've been to a few conferences advertising what they do. It's the letter of recommendation. And these are written in a very, very odd way. They are always exceedingly positive. If there is a hint of negativity in the letter, then that applicant is immediately dropped. And I should say, I should clarify, this is more the American style. The European style is much more cut and dry. And there can be issues if there's a European graduate student applying to an American school and their advisor writes a European style letter saying, oh yeah, this person's pretty all right. that will immediately sink their chances of getting into any job in the U.S. But these letters are very quantified. The letters will straight up say, and I've read and written letters like this, like this student was the third best student I've ever mentored.

But my fourth and fifth best students were so-and-so and so-and-so who went on to this university or this research position. And they had solid lives for themselves. So even though this person is number three, they're a really, really solid bet. They're great. And it's those letters that are the first and last thing they're read. Like you read the whole application. You pour through their academic history. You read their essays to make sure they are competent. You look up their research records. And it's just those letters are so important. And so that's why picking your advisor is so important because your advisor will give you The best letter. This is the person that knows you the best. They've had a direct experience with you for years. And so they're the best judge of your future prospects, of your quality. So getting into grad school, getting an advisor, having a good relationship with your advisor is incredibly important. And those letters just give you the better shot of making it to the next rung.

And if you make it to the next rung and do well there, then that opens up your chances of making it to the next one. Another question I get is, do I need money? Well, undergrad, typically, yes. You know, you need to pay for college unless you get some sort of scholarship or there's some financial assistance. Graduate school, no. You actually get paid to be there, usually from teaching assistantship. So you'll sign up for some department or you'll apply to some department. The department will take you on. You're both a student and an employee of the department. You usually have to teach on the side a few hours obligation per week. In exchange, that department will pay your tuition and give you a stipend. And if your advisor is well-funded, like they've got some money from grants floating around, then they can convert that teaching assistantship into a research assistantship. And then that means that instead of having to teach on the side, you get more time for research. And so that's why...

It's better to go to large, well-funded schools because there's more money sloshing around. There's a better chance your advisor is well-funded or your potential advisor is well-funded so that they can support your life directly and you don't have to teach on the side. But either way, you can always apply for fellowships. from National Science Foundation, from NASA, from Department of Energy. Fellowships are great because it's free money. They usually pay better than teaching or research assistantships. They are naturally very, very, very, very competitive, very difficult to get. But if you get them, you can pretty much say you can set your own agenda in grad school because it's your money. It's not your advisor's money. I can't tell you what to do. And so those are nice. Like I said before, it is exceedingly important to have a good advisor. They're your number one guide through the actual world of academic research. Their evaluation of you will make or break your career. Their connections will become your connections.

The people they collaborate with, the people they write papers with, the big collaborations that they're members of. Those are your initial set of contacts for the next job, for a faculty position, for an opening, for a postdoc, for whatever. They will be your champion. Remember, they hired you. They're spending money on you. They see you as an investment. They want you to do well. Their name goes on all the papers you write to. So they will defend you. They will defend your work. They want you to succeed. So they will, in general, write, unless it's a really toxic relationship, they will write you a very glowing letter. And they will push other people. They will call people and say, hey, I think you should hire this person. Oftentimes in a postdoc review committee or a faculty committee, they will straight up call your former advisor, your former mentor, and say, like, you know, tell me about the, you know, I read your letter. Is there anything you didn't put in the letter that you need to talk about? You know, because we're trying to make this decision.

And they'll be honest. They'll be honest. And that's just the way it is. Another question, what are the skills I need? There's an impression that you need to be really good at mathematics, that you already need to be good at science in order to become a scientist. But, you know, mathematics is incredibly important in the physical sciences, and the book of nature is written in mathematical characters. That's what Galileo said, and it's kind of accurate. But... Being good at mathematics is a skill that you develop over time. Being a research scientist is a skill you develop over time. And you don't get it all at once. So you don't need some great, incredible aptitude at the outset because you train, you spend 10 years figuring this stuff out. You will become a decent scientist whether you like it or not just through sheer force of will over the course of 10 years. And that, I think, is the number one skill. Force of will. Grit. Determination. You've got to want it. I'm going to be honest.

Being a physicist, being an astronomer is not an easy job. Doesn't really pay that well either. Patreon.com slash PM Sutter to help support this show so I can keep going and I can keep supporting all the education and outreach activities I do. Patreon.com slash PM Sutter. Thank you so much for your support. It's not a job that pays well. It's a pretty thankless job. It's not a very glamorous job. Scientists do it for the love of science because they're curious, and this is what it takes to be curious. And so the number one skill – and I've asked around. I've asked other faculty. I've asked postdocs. Just what do you think is the number one skill? And they say to a person, they say determination, grit, perseverance. Yeah. You need it to survive and you need it to break through because it's tough to justify the months of fruitless labor to get that one aha result. That takes guts, grit, determination, perseverance. You need it. It's the only way to make it through. Other skills, the mathematic skills, the analytic skills, the comprehension skills, the debate skills, the speaking skills, that comes with time.

You don't need it now. After 10 years, you'll have it. And you need hustle. You need to do good work and put it where people can see it. I mean, that's true in pretty much any job. There's about 50 papers written in astrophysics every day. Every single day, there's 50 new papers in astrophysics, plus or minus. Nobody can keep up with that. So you got to get to conferences. You need to talk to people. You need to introduce yourself. You need to give talks and defend your work and show people why it's a good idea and why their idea is a bad idea and be open to those debates, be open to being wrong and issue corrections and updates. And that takes hustle. You got to be out there. You got to be visible in the community so people know who you are. So it's like any other career, really. When it comes to careers, there's nothing that special about physics or astronomy. You need an interest or a passion. Otherwise, you never survive. And some base skills, at least a base level of aptitude, at least a base interest in willing to have an aptitude.

The rest comes later. It's part of the training. So I'm pretty much at the limit of how much I wanted to talk. I do have a few more notes about how there's basically no jobs in astronomy. What I think I'm gonna do is I'm gonna save that for a future episode. It won't be the next episode, But I do want to talk about the problems with the modern astrophysics career, physics and astronomy career, of how there are some institutional problems in the community that prevent people from succeeding. I do want to get into that, but I don't want to belabor that today. And so stay tuned. I'll do another episode. It might be a bonus episode. I may not go in the mainstream or something. Just stay tuned to that and we'll get through it. Before I go, I do have two quick announcements. One is Space Radio is live. It's happening. In fact, I just recorded an episode like an hour ago. And you need to go to spaceradioshow.com where you get to talk to me live. We record the show every Thursday at 4 p.m. Eastern.

You need to call 888-581-0708 to talk to me. Just go to spaceradioshow.com. There's all the instructions and info you need. So you can get on the radio and we can have a conversation about science. And the second announcement is AstroTour is back. That's right. With Fraser Cain. I know we're going to Iceland in February 2018. Now we're going to the Caribbean in September of 2018. And you need to come with us. You get to see Kennedy Space Center. Don't go on tour. You get to see the night sky like you probably have never seen before. You get special lectures and talks and show tapings with me, with Fraser Cain of Universe Today. And you get to explore mine ruins in Mexico and Belize. How awesome is that? It is significantly awesome. You need to go to astrotouring.com. Or you can just go to pmcenter.com, my website. That has links to everything. Thank you so much to my top Patreon contributors this month. Justin G., Matthew K., Kevin O., Justin R., Chris C., and Helge B. Thank you so much for your support and the support of everyone on Patreon and all the support for you for listening.

Please... Thank you for watching. adds up and it really, really helps. And I'm extremely grateful and keep those questions rolling in at 92 Rufino and Vicki K. Thank you so much for today's questions. You can keep those questions coming to Facebook and Twitter. My name is at Paul Matt Sutter. You can also use the hashtag ask a spaceman or email ask a spaceman at gmail.com or just visit the website, ask a spaceman.com. And I will see you next time for more complete knowledge of time and space.

Why were the Voyager missions so important? Where are they now, and where are they going? What is their ultimate fate? And that Golden Record…good idea or bad idea? I discuss these questions and more in today’s Ask a Spaceman!

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Hosted by Paul M. Sutter, astrophysicist at The Ohio State University, Chief Scientist at COSI Science Center, and the one and only Agent to the Stars (http://www.pmsutter.com).

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EPISODE TRANSCRIPTION (AUTO-GENERATED)

You know what time it is. It's time for Ask a Spaceman. I'm your host, Paul Sutter. You've got questions and I've got answers. You know how this show works, but let's travel out there one more time. You go online to Twitter or Facebook, use the hashtag Ask a Spaceman and send some questions and I will find them. You can also follow me directly on Twitter and Facebook. That name is at Paul Matt Sutter. You can also go to the website AskASpaceman.com, AskASpaceman at gmail.com, youtube.com slash Paul M. Sutter. So many ways to get questions, but really just one way to answer them. And that is through this show. We have one simple goal with this show. That is complete knowledge of time and space. And on the road to complete knowledge of time and space, we have today's questions. Rob H. via Facebook asking, what awaits the Voyager mission? Ryan asks via email, what is the sun's motion through the galaxy in the direction of Voyager? Wow. Voyager probes. This is historic. I'm recording this episode, by the way, near the 40th anniversary of their launch.

And it's hard to describe just how groundbreaking. Space-breaking? Yeah. Let's go with space breaking. It's hard to describe just how space breaking the Voyager missions were. And they happened at just the right time. It is such a cosmic coincidence, a lucky break at just the time that we were able to actually develop interstellar spacecraft, right? and launch them outside of the Earth's gravity well, send them into space, pack them with scientific gear that could take pictures, that could carry instruments to detect other things, be able to power it, and be able to communicate back with Earth. I mean, think of all the technologies that are packed into a spacecraft and how... 10 years before, 20 years before, 50 years before, 100 years before. That kind of package wouldn't just be impossible, it'd be inconceivable. Go back to the 1800s and try to explain to someone the concept of an interplanetary spacecraft. That's just not a thing that a 19th century mind could wrap itself around. But we're able to do it very, very quickly in the 50s, 60s, and 70s.

And at just the right time in the 70s and 80s, the outer planets lined up. That only happens about every 200 years. 200 years! So if we missed the window, say they lined up in 1910, we would have to wait another 100 years for this opportunity. The planets were in just the right orbit where you can launch them from Earth and swing from gas giant planet, gas giant planet, using the gravity assist to boost the spacecraft each time and kind of hop around like a monkey on a vine from tree to tree swinging from planet to planet. It didn't just make it easy, it made it possible. Because if the planets were on the opposite side of the solar system, you would get to visit one, maybe two. And, you know, that's an expensive mission no matter what, you know, politics and all that kind of stuff maybe just would have never happened. But we did get lucky and we took advantage of it. NASA took the Mariner design, which was very successful for Mars missions, and did two copies, two different spacecraft.

And those were the days when NASA could build two of everything. And sent them, these were the Voyager missions, Voyager 1, Voyager 2, launched from Earth. on a decades-long mission to explore the outer solar system. Do you remember the excitement from New Horizons when it first returned its images of Pluto? And just the fascination and the sense of adventure and excitement and curiosity and how we're seeing things that no one in human history has seen before. It was kind of like that times 10, right? Yes, we had the Pioneer missions before the Voyagers, but those cameras weren't nearly as good. Those were kind of just like test runs compared to the Voyager. The Voyager missions revolutionized our understanding of the outer worlds and brought... our solar system into the popular imagination. You know how like everywhere, like you can, I can just say Saturn and boom, you think of Saturn. It's because of the Voyager missions that I can say Saturn. And you don't just think of a little dot of light or a little blurry image.

You think of a detailed world with cloud bands in the rings and the moons. You can picture it in your mind because of Voyager. Voyager 1 just hit Jupiter and Saturn, plus visited Titan for a bit. Voyager 2 got to visit all four. To this day, by the way, to this day, Voyager 2 is the only spacecraft to visit Uranus and Neptune. Open up any book on the solar system. Search online, solar system. Go ahead, I dare you. If you look up, what is the picture of Neptune? That picture will be from Voyager 2. That's it. That's it. That's all we got, folks. It's hard to describe the amount of data gathered by those missions. It really opened up this frontier, this outer solar system. What New Horizons is doing now with the realm of Pluto and the Kuiper Belt, Voyager did for the outer planets. 30 and 40 years ago. There's detailed images of the Great Red Spot. There's the volcanic eruptions on Io. There's the cracks on the surface of Europa. There's impact sites on Ganymede. It's just, man. So much to discover and so many questions raised by this mission.

Like, what's going on there? What's over here? Why is this happening here? That all modern missions to the outer planets basically go back to the Voyager mission and say, hey, remember when Voyager detected this or saw this or we got this feature? Yeah, we want to figure that out some more. Voyager was the first one. It was not a short mission. It was launched in 1977, hit Jupiter in 1979, Saturn in 1981. Five years later, Voyager 2 gets to Uranus and finally Neptune in 1989. These spacecraft were built tough. They had to operate in the dead of space off and on for decades. And they spent a day tops at each planet. So cruising through space, doing nothing for years and then oh planet mission everything every all systems online full communication full power collecting data for a day and if it's gone they would loop around the total it spent about a month each spacecraft would spend a month around each system but the flybys of the planets themselves lasted about a day In that month, they would get images and detailed observations of the moons of those planets if there are lucky alignments.

But just think about a day like you've been waiting for years and then it's go time and then it's over in a day. The designers of the Voyager spacecraft knew that they would reach interstellar space. Spoiler alert, by the way. So they included a gigantic antenna dish. 12 foot diameter, that's 3.7 meters. That's a big antenna dish. And you're going to need it if you're going to be beyond the edge of the solar system and still communicate with Earth. And it just amazes me how much science and scientific gear the engineers packed into these spacecraft. Optical cameras, infrared and UV spectrometers, magnetometers, plasma wave antennas, triaxial flux gate magnetometer, which sounds way cooler than it actually is. Try saying it three times fast. Cosmic ray detectors, shields, thrusters, computers, targeting sensors, the works. So much stuff is packed into these spacecraft. And they're equipped to not just take pretty pictures, which are very pretty and also very useful, but really study the physical properties and the environment of these systems.

Remember, this was like a once-in-a-lifetime shot. They had to make it work. They had to make it count. They had to take data, they had to do science, gather as much information as possible. So not just a pretty picture of the atmosphere, but temperature differentials across different latitudes, magnetic field strength and penetration of the magnetic field, the whole deal, the whole deal. But enough of what they did. Where are they now? They're about plus or minus 13 billion miles from the sun. That's 21 billion kilometers. As if that means anything. That's just a large number to most of us. It's hard to picture that. That's 140 times further from the sun than the Earth is. Five times further than Pluto is. They've been trucking for a while. They've been going 30,000 miles per hour for 40 years. Some of the fastest spacecraft ever designed, and they've been cruising nonstop for 40 years. They're at such a distance from the sun that even the giant planets are just bright pixels in a grainy image.

Even here on Earth, if you pull out some backyard binoculars, you can see the disk of Jupiter. You can see the disk of the planet Saturn and its rings. Voyager has a much, much better camera than your backyard binoculars, but it's so far away, it can't even see Jupiter, Saturn, Uranus, and Neptune. One of the last images it took was what's called the family portrait, a series of images capturing each planet. And each planet is just like a little tiny dot. If you get out to the distance of Neptune and Pluto, that's like deep twilight. Like, you know, like say an hour into sunset where the sun has definitely gone down, but there's still some light left. That's what it's like at Neptune and Pluto. This is about 1 25th. of that level of light, that level of illumination. I can only imagine it's incredibly weird and isolating out there because the sun is also very small at these distances. It's just a point of light, just like any other star is a point of light, but it is still uncommonly bright.

It would still be painful to look at. You can definitely pick out the sun from the field of stars. Like, yes, that's the sun, but it's not a disk. It doesn't take up any area on the sky. It's just a thin point, but in an uncommonly bright point of light. And Voyager 1 really is in interstellar space. It reached it on August 25th, 2012. Voyager 2 is on the cusp of interstellar space. It'll reach there in 2019. How do we define interstellar space? You know, there's a few definitions that you could pick. The one NASA chose is a good one and good enough for my purposes. I would count this as truly interstellar space is based on the sun's influence, for lack of a better word. Not gravitational influence, that extends technically to infinity, but pretty far. But rather the bubble influence. It's the place where the solar wind meets the interstellar medium. The sun is constantly ejecting charged particles off the surface. And it floods. These charged particles flood our solar system. When they come to the Earth, they interact with our magnetic field.

They get funneled to the poles. We call them the aurora. But these particles extend way out into space, past the orbit of Neptune and Pluto, the Kuiper Belt, the whole deal. But our solar system is embedded in the galaxy, and the galaxy is filled with its own population of high-energy particles, you know, ejected from other stars, ejected from stars. supernova accelerated by magnetic fields. The whole deal, the whole deal. And there's a certain point where you can tell. It tastes different. Where you're like, nope, nope, this is the sun's. This is the sun's charged particles. And then... Nope, nope, nope. This is the galaxy. It mixes together. Almost as if I were to pass gas. No, in an elevator. I don't like that analogy. Let's say you were to pass gas in an elevator. There's a point where the expanding shell of gas coming out of you just mixes with the general atmosphere. And where there's a certain point, if you get further away, you couldn't even tell the difference. It's kind of like that, but made of charged particles.

There's a certain point where the bubble of our sun's influence just mixes and mingles with the galactic milieu. And we give names. Of course, this is astronomy, so we have to give names to everything. We have the solar wind. Eventually, the solar wind stops. It slows down where it meets the galactic interstellar medium. That's called the termination shock. Then there's a region called the heliosheath. and the heliopause after that, and the bow shock beyond that. And of course, it's not just a spherical bubble around us. Our solar system is moving through the galaxy. So it's compressed on one end and extends out the other. Kind of looks like a tadpole. That's our little region, our little tadpole region. For Voyager 1, there are multiple crossings, multiple crossing events where you could tell the difference between the solar environment and the galactic environment. So that suggests that it appears to fluctuate. It wibbles and wobbles back and forth. And that's new stuff, by the way. Voyager 1 is the only one to do that ever.

So we're basing this totally on its observations and its detections. We had no idea where the termination shock might be. We had no idea how thick the helio sheath might be, where it begins to mix from the solar environment to the galactic environment. This is new stuff. And that's pretty cool. So that's in addition. to the Voyager probes, and especially Voyager 1, opening up our outer solar system, reveals what's going on at the very edge of the sun's influence. It really is an interstellar space. It is beyond the influence of our own sun. It is the furthest human-made artifact. We are still communicating with Voyager 1 very weakly. Its power source is dwindling. Obviously, solar power isn't going to get you very far out here, so it has what's called a radioisotope thermoelectric generator. Pretty straightforward concept. You take a lump of radioactive plutonium, stick it in one end of a piece of metal, a semiconductor, and it will heat up the metal. But because you actually have two pieces of metal glued together, they're slightly different materials.

One will heat up faster than the other. because of the heat from the plutonium. And if you have a metal that's hot on one side and cold on the other, you get a flow of electrons, and a flow of electrons is called electricity. So it's pretty easy, straightforward device. It gives long-lasting power. It's like a nuclear battery. That's a good way to think of it. It doesn't last forever, though. One by one, we've been shutting off its systems. We shut its cameras off pretty early. Those are pretty power hungry. Just have a couple detectors, especially to study this helio sheath and helio pause and the bow shock and the determination for all that good stuff at the mix at the boundary between our solar system and interstellar space and to communicate back with Earth and to run the computers. So it's been on low power mode. We can still communicate with Voyager. And by 2025, there will not be enough power to run the antenna. It's a radio antenna, so it will go silent. It would be so quiet. It can't even contribute to Patreon.

Patreon.com slash PM Sutter is how this show and all my education outreach activities are funded by you, the audience, by my supporters. I can't thank you enough. It is your contributions that keep this show going. So thank you. Patreon.com slash PM Sutter to learn more. But Poitier can't even do it. It can't log in. It can't upload its credit card information to make that monthly donation. And eventually its credit card will expire and then it's bad news. So Voyager 1 is outside our solar system. according to that definition of the boundary between the solar wind and the interstellar medium, between the particles ejected from the sun and the particles that are just in the general galactic mix. There is, however, stuff associated with our solar system that's out there. There's the Oort cloud. The Oort cloud is a thin, diffuse shell of frozen debris that was kicked out when our solar system was formed. This is the home of comets that take tens of thousands or millions of years to complete their orbits.

There'll be these little rocks, frozen rocks, Hanging out in the distant parts of the solar system, they can get perturbed, they can get bothered, and they can fall in and swing in towards the sun. It will take about 300 years before Voyager 1 reaches the inner boundary of that Oort cloud. These are objects living in interstellar space, but still gravitationally bound to our sun. Voyager 1, however, is not gravitationally bound to our sun. It will keep going and going. It will never return. It will eventually pass by another star coming within 1.6 light years of a star called Gliese 445. And you know what? That sounds super far away. But when we're talking interstellar distances and galactic scales, 1.6 light years is pretty close. That will happen, by the way, in 40,000 years. Voyager 2 should reach interstellar space, we think, in about 2019, depending on its exact boundary of the heliopause. It, too, will pass by a star in about 40,000 years. It will come within 1.7 light years of Ross 245.

It will also come within 4.3 light years from Sirius, the brightest star in the sky. That will happen in 296,000 years. And then nothing. That's it. These are galactic scales. These are interstellar scales. And I love introducing the topic of Voyagers. I love talking about the Voyager probes in talks because it really hits home what it means to be interstellar, the true scales of our galaxy. It's like a punch in the gut when you really think about it. It took 40 years for Voyager 1 just to reach the edge of this bubble and see, like, oh, space isn't that big. That's four decades. That's not so bad. Oh, and then to even reach another star, 40,000 years. And then that's it. It's hard to predict, of course, because there is some chaotic motion to star movements. You know, new stars can be born and die. There can be molecular clouds that disrupt. But we're pretty sure it's never going to get that close to any other star ever. Our Milky Way galaxy is made up of hundreds of billions of stars.

And Voyager 1 and Voyager 2 will never encounter another one. Ever. Ever, ever, ever, ever. That's it. Forger one got to be close to our son and get to be close to Glees 445. Forger two will get close to Ross 248 and then kind of sort of close to Sirius. And that's it. The sun is sitting about two-thirds of the way out from the center of the Milky Way galaxy, situated on what we call the Orion Arm, one of the spiral arms of our galaxy. The sun itself has a speed of around 200 kilometers per second, so the speed of the Voyagers is that plus 38,000 miles per hour, which is still 200 kilometers per second, about. The Voyager probes themselves were launched going in front of the sun, so they take the speed of the sun, plus that they're kind of going out ahead of us. They really are voyaging out ahead of us. Going slightly up-ish and slightly down-ish, the interactions they had with the planets sent them on these slightly different trajectories. So they're not gonna keep going straight ahead of us in the galaxy in our direction, in our own orbit around the Milky Way, so they'll go up and down a little bit.

In 200 million years, they will circumnavigate the galaxy once. 200 million years after that, they'll do it again. It's weird to think about if you were attached to the Voyager spacecraft, wouldn't you be dead? But let's assume you were alive. Just the loneliness of being out there. Where slowly year after year our sun gets dimmer and dimmer and dimmer until you can't even tell it apart from the field of stars that surround you. And then dimmer still so you can't even pick it out. You can't even see it. And then dimmer still where you can't even pick it out with a telescope. And you'll pass by some other stars. Some will get brighter. Some will get dimmer. But that's it. You're never falling into another solar system. You're never seriously encountering another object. Nothing bigger than a microscopic grain of dust. A cosmic ray here and there. That's all you'll ever touch. That's all the Voyager spacecraft will ever touch. The story... of the voyager spacecraft isn't quite over even though their mission will end in 2025 no more communication no more data that we can acquire from those spacecraft there is something else on both spacecraft there's uh tucked between the instruments on the side is a small golden disc And we've etched some carvings into those disks.

Diagrams of people. You know, there's the dude waving high and the lady just standing there. Same as the pioneer plaques. The location of our sun relative to nearby known pulsars. And there's some basics about the hydrogen atom and the 21 centimeter emission line. Some basic facts that we think are totally universal. And there's some instructions. There's a little pictogram. And you could, it's hoped, look at this pictogram and realize that they're instructions. And if you follow the instructions, you end up assembling a spinning platform and a little stylus. And then you can take this golden disc, set it into that spinning platform and set the stylus in the grooves that are etched into the disc and start spinning the disc. And the stylus will start vibrating. And then you can interpret those vibrations as sound waves. And you could listen to those sound waves and those sound waves would carry information. There'd be some basic facts again, kind of establish what's going on. And then you would start to hear voices, sounds of nature, you know, crickets chirping in oceans crashing against the shore.

And then you'd hear music. There's a selection of songs placed on these interstellar spacecraft. It's taken from around the world. If I had to judge it, it seems kind of biased towards Western classical music. But there's a lot of cool stuff on there. And apparently, you would be wowed and brought to tears by that selection of music. And... This is like this is considered it was considered an emissary of Earth. Like, OK, definitely this golden record is going to outlive the designers and creators. It was led by a committee led by Carl Sagan, Frank Drake, you know, all the usual suspects. And it will definitely outlive them. And, you know, there's a pretty solid chance it's going to outlive humans as a species. And so like this is it. It's like a time capsule. of our time here on earth and an emissary like here's a little slice of our world a little slice of what we experience and a little slice of of us of our own culture of our own values of of who we are there's lots of recordings of people saying hi in various languages and the the the hope is the romantic hope is that you know someday eon literally eons from now Some civilization might encounter a Voyager spacecraft, recognize the golden record for what it is, follow the instructions, construct a spinning platform, look at the vibrations on the stylus, correctly interpret them as meaningful information, listen to the sounds and be like, oh, wow, okay, cool.

I honestly can't decide. If the Voyager golden records are this bold, noble emissary into the great void, the everlasting record of humane, a small piece, as small as it could be, as it is, it's still a part of us, and it's now permanently a part of us. So even in four billion years when the sun consumes the earth, when it dies, we've still got the Voyager probes out there with a little piece of our culture and who made them. I can't decide if that's cool or kind of silly because we know that those Voyager spacecraft are not going anywhere anytime soon. And the chances of the Voyager spacecraft coming within range of any star system are literally astronomically small, let alone one that is full of intelligent beings that could spot the Voyager spacecraft. They are kind of small after all. Toe it in, do all the stuff, gather meaningful information, and actually listen to the golden records. So it's... It's kind of, in one view, it's kind of self-serving and narcissistic. Like, oh, we need to make our mark on the universe.

So we have to send the golden records out just on the off chance that someone will encounter them. They have to know that we were here. They have to know that we existed. That seems, I don't know, that just strikes me as narcissistic and self-serving. Like, we're not doing it for them, whoever might encounter it, whoever they are. We're doing it for us to make ourselves feel good. But on the other hand, it's kind of noble and beautiful and poetic that we do have this emissary out into the great void. So is it a good idea or a bad idea? Is it silly or noble? I honestly don't know. I go back and forth. And I'd love to hear your thoughts on Twitter and Facebook. Go ahead and shoot me. What do you think? What do you think of the Golden Records? Good idea or silly idea? Let me know and I'd love to have that discussion with you. Thanks so much to my Patreon contributors this month, especially my top ones, Justin G, Matthew K, Kevin O, Justin R, Chris C, and Thanks to all the Patreon contributors, patreon.com slash pmsutter for more info.

And of course, thank you to the people who asked the questions for today's episode. Rob H. on Facebook and Ryan S. via email. Beautiful subject, the Voyager missions. The scientific return is enormous. Thoughts of where they are and where they will be. very sobering and then open up this interesting question on the voyager golden records thank you so much thanks again you can follow me on twitter and facebook directly at paul matt sutter love to hear your thoughts on this episode you can also go to the website ask a spaceman.com send questions to ask a spaceman at gmail.com go to youtube.com slash paul m sutter go to itunes and submit a review that really helps the show's visibility i really appreciate it and i'll see you next time for more complete knowledge of time and space

What does it mean for an electron to spin? Why do we have such a hard time measuring it? And why doesn’t Paul Dirac get any attention anymore, anyway? I discuss these questions and more in today’s Ask a Spaceman!

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Hosted by Paul M. Sutter, astrophysicist at The Ohio State University, Chief Scientist at COSI Science Center, and the one and only Agent to the Stars (http://www.pmsutter.com).

EPISODE TRANSCRIPTION (AUTO-GENERATED)

You know what time it is. It's time for Ask a Spaceman. I'm your host, Paul Sutter. You've got questions and I've got answers. You know how the show works, but let's take it for another spin. You go online, Twitter, Facebook, use the hashtag AskASpaceman. Send me some questions and I will pick a small subset of them to answer on this show only because there's a lot of questions and not a lot of shows. I got to work on that. You can also email me directly at AskASpaceman at gmail.com. You can also go to AskASpaceman.com. or youtube.com slash paul m sutter to check out the videos all those places can accept questions how awesome is that we have one simple goal with this show complete knowledge of time and space and on the road to complete knowledge of time and space we have today's questions from so many people asking the same question this is fantastic we've got dean b via email what is fundamental spin we've got p e via email how does an electron have quote unquote spin we've got at n-i-r-b-n-z on twitter could you explain once and for all what does the spin property mean in quantum mechanics We've got Kerry Kael via email.

Why are so many things spinning? Where does that energy come from? We've got at Sojournal via Twitter, 10 bucks. If you can explain the spin of the electron. Now, I don't often take bets. But you know what? At Sojournal, as you're listening to me, prepare an envelope. I want you to put on that envelope the address Paul M. Sutter, P.O. Box 3322, Columbus, Ohio, 43210-3322. You can put that $10 in that envelope because I think... At the end of today, you're going to owe me 10 bucks. I think we're going to do it. We're going to do quantum spin to your satisfaction. I'm laying it out there. I'm laying it out there. I haven't even recorded. I don't know how well this is going to turn out, but I've got a good feeling about this. Now, since I don't often take bets, I don't want to just take your money and do something frivolous with it. I want you, this is going to be a game. I want you to choose a cheese. That's right, a cheese, and I will buy that cheese and eat it with your $10, and I'll put the picture on Twitter.

I know you're thinking this is a little out of left field. It's just never come up before. I love cheese. I like cheese. In fact, if you just want to mail me cheese directly instead of contributing to Patreon, that's P.O. Box 3322, Columbus, Ohio, 43210-3322. I'm a big fan of cheese, and I can't believe in the years that this podcast has gone on, it's never come up. But there it is. I believe 90% of my diet is cheese. But seriously, you know what? If I've successfully explained spin, I want to reward myself. You know, I want to congratulate myself. I don't often congratulate myself. And what better way? than with a good cheese. Now, first things again to everyone for all the amazing and thought provoking questions you've asked all these years. I can't thank you enough. This show drives on your questions and you are all definitely curious about more than I thought you would be like spin. good old spin, quantum spin. When I started this show, I never thought I'd get questions about spin, but here I am.

And you know what? I'm pretty happy for it. I love talking about astronomy, astrophysics, and quantum mechanics. But as you know, quantum mechanics is such a thick, rich, dense soup of a topic. It is, after all, an entirely field of physics. It's hard for me to find entry points, little dabbles here in quantum mechanics, but spin, in my opinion, is the classic, that's not the right word, the prototypical quantum mechanical subject. And it's a great way to start entering into this quantum world and working it into the show is through spin. And yes, there's all the sexy quantum mechanics stuff like superposition and probabilities and entanglement and teleportation and spooky action at a distance. And that's all great. That's all cool stuff. And historically speaking, if I wanted to follow a narrative of our development of quantum mechanics, we started figuring out all that stuff before we figured out spin. But you know what? That stuff and don't worry, I'm sure eventually I'll get to do shows about all that stuff.

A lot of that knowledge, a lot of that language, the perspective of looking at quantum mechanics is due to a particular physicist by the name of Erwin Schrodinger. And you may have heard of Schrodinger's equation or Schrodinger's cat. That's a long story on the cat thing. So feel free to ask. But all that stuff. All that good stuff, superposition, the uncertainty principle, things like that, that's just waves. The Schrodinger equation, the mathematics that's used to describe a lot of quantum mechanics, is a wave equation. It's an equation that describes the behavior of waves. So superposition, uncertainty principle, normal waves do that too. It's just in quantum mechanics, they acquire this new interpretation. But there's a lot of analogies that we can use in the macroscopic world where we can take things that we're already familiar with. And because the equations are exactly the same, they're just applied in a new scenario. We can build some mental models. We can make some analogies. And that's all great, except for spin.

There's nothing quite like spin. And as I'm about to tell you, I think spin is a purely quantum mechanical thing, despite its name. And I'll get to the whole name thing. There's nothing quite like it in the macroscopic world. And so what's the big deal? What's the big deal? Let's start with an electron. How many numbers do you need to totally describe an electron? Well, an electron has mass. There's one. It has charge. There's two. So at least two numbers you need to describe any electron in the universe. But some experiments in 1922 found something funny. These two physicists, Otto Stern and Walter Gerlach, shot some silver atoms through a magnetic field. And apparently, no, no, no, shot some silver atoms through a magnetic field. And apparently they had some motivation for doing this and they weren't just bored. They were intent on looking at this. And as the atoms passed through the magnetic field, they got deflected. Their paths got bent away from a straight line. Hmm, that's interesting.

Not totally unexpected, but that's pretty cool. Okay. Shooting these silver atoms through the magnetic field and their paths get curved. But they got curved in two directions. The beam of atoms was split. Some atoms would curve up and some atoms would curve down. down and it's at this point in the life of a scientist where you go from okay okay pretty cool result that's nice to uh stern and gerlach pretty much had no idea what was going on And remember, the magnetic field in their apparatus, in their experiment, isn't changing. It's just staying there. Nothing's changing about the beam of silver atoms being shot through the magnetic field. They just turn it on and go. But something, somewhere, somehow is making a decision. Each silver atom chooses, for lack of a better word, to go up or down as it gets shot through this magnetic field. How do we even begin to explain this? Presumably, that's what Stern and Gerlach said, but in German. And seriously, until 1922, nothing like this had been encountered before.

Nothing. This was a very unique thing. This was a very, very special thing. If you pretend... You know nothing about electrons and atoms or quantum mechanics. We do know about how charged objects operate in magnetic fields. We do know that if you have a metal ball, let's just say you got a metal ball and it has an electric charge. It can interact with a magnetic field. It can spin in the same direction as the magnetic field. So the magnetic field is pointing in one direction and then the axis of this spinning ball can point in the same direction or it can point in an opposite direction. It can point in any direction you want. And if it's not pointed in the same direction as the magnetic field, then the magnetic field can push on that charged metal ball to rotate it. This is very simple, James Clerk Maxwell, electrodynamics, seriously kindergarten level physics. I mean, learned this decades ago. And if you take these spinning charged metal balls and shoot them through a magnetic field, they'll get deflected.

So it's that easy, right? Like if we're performing this experiment with not silver atoms, but with giant metal balls, it would be very, very simple to interpret. We would get a very, very simple result, which would be, yes, the paths of these charged metal spinning balls would get deflected. They would end up on the opposite side. And so the natural intuitive, the first thing a physicist's mind goes to when you see this result of the silver atoms and then very, very quickly we realized it wasn't the silver atoms doing the work, but the electrons themselves. The first step, the first thing you think of is, oh, electrons have an extra property. They don't just have mass. They don't just have charge. They also have this property, and we're going to call it spin because it seems to act like an electron is a tiny spinning metal charged ball because that's what would happen if we were to run this experiment in 1850 or whatever. That's what would happen to the spinning charged metal balls. So this is, the electrons are doing pretty much the same thing.

And so they have an extra property. We'll call it spin because that seems to work well. So we can think of electrons as tiny little charged metallic balls and they're spinning really, really fast. And then when you shoot the electrons through a magnetic field, some will randomly be pointing up, some will randomly be pointing down, and that's how you get your split. Now, I want you to take that nice, neat, tidy, cozy little explanation, that understanding you have in your head of how an electron works like a spinning metal ball when we shoot it through a magnetic field. I want you to take that notion and put it in a box. I want you to lock that box. I want you to throw away the key. I want you to light that box on fire. I want you to take those ashes and put them in another box. And lock that box and throw away that key. And then I want you to attach that box to NASA's Parker Solar Probe as it crashes into the sun. I want you to never think of an electron like a spinning metal ball. Ever again.

And I mean it. Why? Because it's wrong. And this was realized right away. For one, we can calculate. given simple electromagnetism, how much the electron should respond to the magnetic field. This is a quantity called the magnetic moment of the electron for the curious. And if you have a spinning charged metal ball, you can calculate for how fast it's spinning, how much is charged, how massive it is, how much it ought to react to a magnetic field. And you apply those numbers to what we know, the mass and charge of an electron, and you get the wrong answer. And we know that electrons are really, really, really small. In fact, they may be infinitely small. That's another episode. And if they're just the size of our current detection limit, if they're just below that, if we think they're a certain size, that means to get that kind of a magnetic moment, the one we actually measure, that kind of reaction to a magnetic field that we actually measure, it means they're spinning faster than the speed of light, which is kind of wrong.

And if all the electrons being shot through this magnetic field had random spin directions, if they moved all over the place, if you imagine like these little arrows attached to the electrons, then some will already be pointing in the same direction as the magnetic field. Some will be a little bit off. Some will be way off. They should get tossed around randomly. If they have random spin directions, they should get spread out randomly and evenly on the opposite side. Because some will react strongly based on their spin and some will react weakly. Some will get deflected a little bit. Some will get deflected a lot. So it should be spread out evenly. Instead, they separate into two and only two camps. And this is the real kicker. Because no matter how we measure it, we always only ever get two answers for how much the electron is spinning. It's always either up or down. And the amount of upness and the amount of downness is always the same. We don't see any intermediate values. We don't see this nice continuous spread on the opposite side of the instrument.

We only see two clumps. And that is something that normal spinning metal balls simply wouldn't do. To sort this out, to really put us in the right perspective, we have to go in a fully quantum mechanical state of mind. We need to put blinders on either side of our eyes so we resist the temptation to apply our normal everyday macroscopic experiences and expectations of the world to the subatomic realm. Down there, things are simply different and it's not going to make intuitive sense. But nature doesn't care if nature makes intuitive sense. She doesn't care. Nature is nature. Electrons are going to do what they're going to do. And we have to, we absolutely have to discard. our classical worldview. Just like we do for relativity, we have to do it for quantum mechanics. The rules are simply different down there. So now we must go down that quantum road, full speed ahead, unwavering, unflinchingly, no stopping, except for one pit stop for Patreon. Patreon.com slash PM Sutter is how you can support this show and keep all the episodes going.

And the YouTube show, like every education outreach thing I do, it's supported all by contributions like yours at patreon.com. I can't thank you enough. And if you can't, I know I tease you that you ought to contribute even if you can't. Believe me, that is just a joke. If you can't contribute, I still appreciate you just listening to the show. If you can tell someone, if you arrive you on iTunes or Google or on the website or tell people on the internets, I really appreciate that too. Thank you so much. Now that we've had that appropriate stop, we can continue down the quantum road. In the early days of quantum mechanics, I mean, wait, like 1910s, 1920s, physicists really around the world were coming up with all sorts of rules to explain the subatomic world. There were all these experiments going on, you know, revealing what's happening to atoms and particles. And the physicists, the theorists were really trying to catch up, like piece it all together, put it into some coherent framework.

And they did. They had things pretty much sewn up tight in a compact set of mathematical descriptions, which is another episode, except for spin. So they were able to explain all these interesting, complicated phenomena, except for spin. And spin was just kind of tacked on. So they said, like, here's a self-consistent, elegant, beautiful description of the microscopic world. And then here's some stuff on spin. And of course, as the rules were developed, as we learn more about what quantum spin is really like, shorthand and notations were developed. And they seem, when you first encounter these shorthands and notations, they seem non-intuitive and awkward. And that's because they're non-intuitive and awkward. So what are some of the rules of quantum spin? Well, first it's, you guessed it, it's quantized. What does quantized mean? It means it comes in little packets or steps. The difference between the classical and the quantum world is the difference between a nice gentle slope in a staircase.

A nice gentle slope, I can choose to be anywhere I want on that slope. I can just be a little tiny bit. I can be a lot. I can step down just a little bit. I can go half a step, a quarter step, an eighth of a step. It doesn't matter. The slope lets me be anywhere. But on a staircase, I can only be on one step at a time. If I try to walk in half steps, I'm going to fall over. I can't do it. I can only go on this step, the number two step, number three step, number four step, number five step. And that's it. That's what the quantum world means. Things like angular momentum, things like energy only come in little packets, only come in steps. You can't have anything you want. And this is showcased really, really well with spin. When it comes to spin, an electron can only be measured to have, and here's a notation, here's a definition, either plus a half or negative a half spin. That's it. If you go to measure the spin of an electron, like, hey, how much is that electron spinning? You'll only measure one of two numbers, plus one half or minus one half.

And the one half, again, that's just a notation, a definition, a way to kind of untangle this mess. There are other kinds of particles than electrons, of course. Some kinds of particles can have three values of spin. They can have one. They can have zero. Or they can have minus one. Some other kinds of particles can have four measurements of spin. You can get plus three halves, plus one half, minus one half, or minus three halves. Even others can have five measurements of spin. Two, one, zero, minus one, or two. There are two kinds of spin. And all particles in the universe are either halfers, spin one half, or they're holers, spin one or spin two or spin three. And we've encountered this before. These kinds of particles have names. The fermions are the halfers in the universe. They are the ones with spin half or spin three halves or five halves. And the bosons are the holers. These are the spin zero, the spin one, the spin two. And I need to do a whole other episode on how this spinniness, that's my name, by the way, determines what kind of particle is and what are the implications.

That's a whole other episode, super fun, but not the subject of today. So an electron, let's go back to electrons. You can only see, you can only measure the spin of electron. You only have two values that will come out of your experiment, either plus a half or minus half. And I need to talk a moment about this concept of measurement. Because a lot of times you'll read or even I'll say like, oh, the electron has spin plus one half. I'm actually being a little bit lazy when I say that. And this is a very subtle point, but I think it needs to be made because this cuts right to the heart of quantum mechanics. Let's say I have a box of electrons, a big old box, lots of electrons. They can have any spin direction they want. Like the analogy I used before, imagine a bunch of little arrows, right? painted on all these electrons. And that arrow represents their spin direction. They all have the same magnitude of spin. So they're all spinning at the same rate, but they can be oriented any way they want.

All the electrons are jumbled up, so the arrows point all over the place. Then I start throwing them through the magnetic field. The magnetic field has a direction to it. It has an up and a down sense to it. For each individual electron, it has a little arrow being shot through this apparatus. That arrow will be maybe it's pointing up and a little bit sideways. Maybe it's pointing mostly sideways and just a little bit up. Maybe it's almost exactly split at a diagonal halfway between sideways and up. It doesn't matter though. It doesn't matter what that orientation of the spin is. I will only ever measure the arrows pointing straight up or straight down. I don't get to learn about how much the arrows are pointed left or right. This is a fundamental limit to measurements in the quantum world, and it's kind of a big deal. Imagine, imagine, imagine you bought your new smartphone. It has GPS, it has maps in it, turn-by-turn navigation. You're super excited. You plug it into your car and you say, hey, I want to go to that restaurant.

And instead of giving you accurate directions like, oh, you need to travel north-northeast for one mile, then turn left, you know, all the instructions. What if instead there's only two lights, right? And lights tell you north or south. And that's it. So let's say, well, if you say, oh, how far to that restaurant? Oh, it's two miles north. And then you travel two miles north. And then you ask again, hey, where's the restaurant? Oh, it's two miles south. So you travel two miles south. Okay, now where's the restaurant? It's two miles north. No, no, no, it's two miles south. No, no, no, it's two miles north. And that's the only ever answer you can get out of your GPS. You would immediately throw it in the trash. Unfortunately, we can't throw nature in the trash. We're stuck with it. This is a fundamental limit of measurement. The electrons can have whatever spin they want. If they're pointing just a little bit up, just a hair up, we will measure it as all the way up, spin plus half. If they're pointing just a little bit down, Just a tiny, tiny, tiny bit down as they're thrown through this magnetic field.

We'll measure them as negative one half. And that's it. That's all we will ever measure. Ever. We don't get to learn how much left or right. We don't get to learn how much up or down. Just if it's any bit up, it gets counted as up. And any bit down, it gets counted as down. Now, if I repeated my... Magnetic field Stern-Gerlach experiment apparatus. Instead of having an up-down magnetic field, I rotated it so it was a left-right magnetic field and repeated the experiment. Then I would get to learn about the electrons left-right. Are they pointing left? Are they pointing right? But I don't get to do it at the same time as the up-down. In fact, I destroy my knowledge of the up-down. And I can't do it at the same time. I never get to learn both simultaneously. So there's a limitation in the direction I can measure an electron spin. I can only measure its uppiness or its downiness. And I never get to learn how much of uppiness or downiness. Just are you in the up bucket or are you in the down bucket? And that's it.

So that's what spin is. Electrons and all particles have this weird property that we call spin. Different particles have different allowed values of spin, but we are fundamentally limited in how well we can measure it. And this is why this experiment, this 1922 experiment by Stern and Gerlach is so striking because usually the effects of quantum mechanics are really subtle. Like you have to do these really detailed measurements and you tease out the quantum nature and it's all spooky and weird, but very deep down, this is like a tabletop experiment that you can do at home and blasting right in your face is the true nature of quantum mechanics. right there, and you can't get around it. How are we gonna make sense of this? Where does this property of spin come from? What does it mean? Well, like I said, in regular quantum mechanics, all this stuff, quote unquote, regular quantum mechanics, by the way. All this stuff is just tacked on with the justification, experiment said so. Like we have this grand, beautiful, theoretical infrastructure to explain quantum mechanics.

And then here's some rules of spin that we can't really predict. And by regular quantum mechanics, I mean the Schrodinger equation. The Schrodinger equation does not include spin in its mathematics. That equation is a whole other episode, but I need to bring it up because Schrodinger wasn't the only person to work on quantum mechanics. He wasn't alone. There was lots of people. And now it's time. There's someone else I need to introduce. One of my all-time favorite scientists. I mean, James Clerk Maxwell, don't worry, still king of the mountain. But putting up a good fight for that. Oh, my gosh. Paul Adrian Maurice Dirac. Paul Dirac, just a beast of a scientist. I am not joking around. By the way, he signed his papers P.A.M. Dirac. So people would wonder why I signed my own papers P.M. Sutter. There's the inspiration for that. Paul Dirac just made things happen. He wouldn't just solve problems. He would develop new mathematical techniques on the fly to solve those problems. And then decades later, actual mathematicians will go back and prove that what he did by pure intuition was actually legit.

This is the kind of guy that could and did go toe-to-toe with Einstein and win. He shared his Nobel Prize with Schrodinger in 1933 for developing quantum mechanics, but he doesn't get as much love today. You know, the Schrodinger equation is everywhere, if you pay attention to that kind of stuff. But outside of physics, he's not really in popular culture. But inside of physics, his name is on like half the stuff. Like the Dirac this, the Dirac that, the Dirac operator, Dirac function, the Dirac equation. He gets plain name recognition inside the world of physics. And here's why I'm bringing up Dirac. Here's the deal. Quantum mechanics was developed in roughly the 1920s. By the 1920s, special relativity was already old news. Einstein developed that in 1905. And everyone knew that special relativity was a thing. And if you're going to make a theory of nature, if you're going to describe some aspect of nature, it has to incorporate special relativity, the rules of special relativity. Schrodinger attempted to make an equation that described what the experiments of quantum mechanics were revealing, but also obeyed the rules of special relativity, what we knew to be true from a special relativity.

That equation didn't make any sense at all. So he abandoned it. He said, let's just let's just figure out all that special relativity stuff later. And instead, he went casting about found the existing language of wave equations, was able to apply that successfully to quantum mechanics. And that's our Schrodinger equation, using that to like interpret and understand our results from those experiments. So you can use the Schrodinger equation to make predictions and knowing that it's not going to be correct in pure special relativity. So it's an incomplete picture of nature. Then comes Dirac, who at about the same time is doing the same similar work. He wants to develop some equations to describe what the experiments in quantum mechanics are saying. But he really, really wants to bring in special relativity. He really wants to make this happen. He arrives at the same place Shrody did, and he figured it out. The trick, because initially these equations make no sense at all. The trick was to, you know, completely restructure the mathematical description.

So instead of casting about for some existing language, he invented a whole new language. He said, no, no, no, no. Here's how you interpret it. You're going to speak a new language. That equation, the Dirac equation, describes everything the Schrodinger equation does and more. It includes special relativity. So it's like having two languages to describe the same phenomena. The Schrodinger equation is based on one language, the language of waves, and we can use it to make progress and make understanding The Dirac equation includes the Schrodinger equation and so much more in a completely new language. That's another episode to really dig into that, what that language is and how we interpret quantum mechanics via the Dirac equation. It includes the Schrodinger equation, includes special relativity, and it includes spin. The concept of spin. naturally appeared in Dirac's solution for quantum mechanics. If spin wasn't already discovered, he would have been credited with predicting it. He ended up getting vindicated, though.

His equations not only included the Schrodinger equation and special relativity and spin, also naturally included something we had known before, something we now call antimatter. Antimatter was predicted by Paul Dirac in this exact same equation. So what is spin? Well, it's a horrible word for one. Spin, the concept of spin is based on our classical understanding of electrodynamics that simply do not apply to the quantum world. Better term might be, I don't know, magnetic response of a particle. I don't know. I guess there's no word. We should have just made up a word. We should have made up a word and we'd be so much better off. If you're lazy, you can think of it like an actual spinning metal ball. like pretend these little particles are charged metal balls. And, but let's not, let's not. And you know what? We're never going to speak like that again. Spin is built into the universe. Asking where it comes from is like asking where mass or charge comes from. It seems to be fundamentally connected to the relationship.

between quantum mechanics and special relativity. So at one level, you can think of it as just a set of rules. Like, hey, nature says there's this quantity called spin, and it's different kinds of particles that have different amounts of spin, just like different particles can have different amounts of charge or mass. But because of the rules of quantum mechanics, we're limited in how much of that spin, of that quantity, we can actually measure. But spin appears to come. instead from this unification between quantum mechanics and special relativity. It appears to be something much, much deeper than a set of rules. It's at this point, and it's so cool, it's so cool that you can do a tabletop experiment, See this quantum mechanical effect, which is usually super subtle. Quantum mechanics is not easy to tease out, but there it is right in your face, making itself manifest, making itself known. And not only is it this manifestation of quantum mechanics, it's at this intersection between quantum mechanics and special relativity.

Is that confusing? Too bad, Mother Nature doesn't care. I'd like to thank my top Patreon contributors this month, Justin G, Matthew K, Kevin O, Justin R, Chris C, and Helga B. Thanks so much to you and all my Patreon contributors, patreon.com slash pmsutter, to help make this show possible. Be this show. And thanks again. The other part of making this show, this show is the questions. I'd like to thank Dean B, Pete E, at Nurbans, Carrie Kale, and at Sojournal, who is going to send me 10 bucks. P.O. Box 3322, Columbus, Ohio, 4320-3322. Please. keep those questions coming. Go to ask a spaceman.com. You can follow me directly on Twitter at Paul, Matt Sutter, also on Facebook, also on youtube.com slash Paul M Sutter. Uh, go to iTunes, go, go forth and spread the word of spin. And I'll see you next time for more complete knowledge of time and space.

What’s the balancing act happening inside stars? Why is iron the fusion limit? How long does it take for a star to blow? I discuss these questions and more in today’s Ask a Spaceman!

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Big thanks to my top Patreon supporters this month: Justin G., Michael Z., Kevin O., Justin R., Chris C., Helge B., Tim R., Michael C., Lars H., Ray S., John F., James L., Mark R., Alan M., David B., Silvan W., Edward H., and Alex P.!

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Hosted by Paul M. Sutter, astrophysicist at The Ohio State University, Chief Scientist at COSI Science Center, and the one and only Agent to the Stars (http://www.pmsutter.com).

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EPISODE TRANSCRIPTION (AUTO-GENERATED)

You know what time it is. It's time for Ask a Spaceman. I'm your host, Paul Sutter. You've got questions and I've got answers. You know how this show works, but let's blow it up one more time. You go online to Twitter, Facebook, use the hashtag Ask a Spaceman. I'll pick those questions out and I'll blast an answer right back to you or six months later or two years later, but eventually an answer will get back to you. You can also follow me directly on Twitter and Facebook. My name is at Paul Matt Sutter. You can also go to the website at AskASpaceman.com. Leave some comments on the episodes. You can have a conversation there. It's all good. You can also go to YouTube.com slash Paul M. Sutter. We have one simple goal with this show. Complete knowledge of time and space. And on the road to complete knowledge of time and space, we have today's questions from at Ianut Branea. asking, why do supernova happen? I don't understand what triggers the explosion. And also, why is iron the limit when fusion stops inside a star? And also, at thomaspadden1, also on Twitter, supernova, coolest or hottest thing ever? Great questions.

And today, I'm going to give you a simple recipe that you can follow at home to make your own supernova. You need a load of hydrogen. Around 10 to the 31 kilograms or two times 10 to the 31 pounds. Don't worry if you're a little bit off. This measurement doesn't have to be exact. You need a dash of carbon, nitrogen, and oxygen. Set your oven to 10 million Kelvin and set your timer to around 10 million years. And all you need to do is wait and eventually you'll get... The big boom. A supernova explosion. It is just that easy. It's crazy to think how simultaneously simple and complex the natural world can be. It's a very simple ingredients. It's a very simple process. And yet it leads to this incredibly rich, dynamic situation and one of the most powerful explosions in the universe. That simple process. that takes all these ingredients the hydrogen the carbon the nitrogen the oxygen and turns it into a supernova is gravity it's all driven by gravity good old-fashioned newton and einstein down at the bottom of your feet gravity gravity plus time gives you supernova chew on this The same force.

The same force that holds your feet to the ground is the exact same force that provides the energy required for a star to go supernova. That is one of the most beautiful things. One of the things I really love about physics is the universality of physics, how the same physics here on Earth apply across the universe. And the understanding that we develop to figure out why our feet stick to the ground help us understand some of these crazy exotic phenomena happening on the other side of the universe. And I need to say, so much of astrophysics is driven by simple gravitational collapse. You have a cloud of stuff. It's unstable. It starts collapsing in on itself. You get galaxies. You get galaxies. Stars, you get supernova. This is an example of the power of gravity. Sure, gravity may be the weakest of the four forces, but it can play some tricks that the others can't. Just give it, you know, a few million years. In the case of stars, it's a balancing act. You have a giant blob of hydrogen, and gravity is pulling it together.

Gravity is what pulls it into a spherical shape. Gravity would love for the star to collapse into an infinitely dense point. That's all gravity desires, is to take stuff and squish it down even tighter. But it gets stopped. It gets prevented from squishing that star down into an infinitely dense point because... The deeper you go into the core, as all this material is compressing in on itself, the deeper you go, the higher the pressures get, just like diving into the ocean. The gravity of the Earth would love to pull the ocean down into the core. And so as you go lower and lower in the ocean, the pressures get higher and higher. Higher pressures when it comes to gases like the sun or a star, higher pressures mean higher temperatures. eventually. The pressures are so high that protons, who normally hate each other and want nothing to do with each other, they are like charges, so they repel. They are forced to live together inside the same nucleus, and that's a fusion party. The pressures, the gravity delivers a enough overwhelming pressure.

In fact, this is the definition of a star. The dividing line between a planet or a brown dwarf and a star is, is there enough gravitational pressure at the core to ignite a fusion reaction? There's two main chain reactions that happen to convert hydrogen into helium. And since I'm talking about supernova, I'm going to talk about more massive stars. Stars at least around eight or so times more massive than the sun. And in this reaction, you start off with four hydrogen atoms. And you sprinkle in some carbon, nitrogen, and oxygen. And these act like a catalyst to... shall we say, enhance the reaction. They make the nuclear chain reaction go faster than it normally would and be a little bit more energetic than it normally would. At the end of the day, you start off with four bits of hydrogen and some sprinkling of carbon, nitrogen, and oxygen. They return. You still keep the carbon, nitrogen, and oxygen. They get recycled to be used in another reaction. But instead of four hydrogen atoms, you get a helium atom.

And the helium atom is slightly less massive than the original four hydrogen atoms. And we live in a universe where mass is equal to energy. And so this process gives off energy. You lose mass, boom, you get some energy out of it. This process, this nuclear reaction has a few other byproducts. It spits out some positrons, which are the evil twin of the electron. I need to get into antiparticles someday. Just ask the question. Spits off a couple neutrinos, and neutrinos, a very ghostly particle, usually don't play a role, but they'll become important later. And of course, photons, light, radiation. Ladies and gentlemen, this is a nuclear bomb. A fusion bomb, to be precise, a hydrogen bomb. And what do bombs do? They explode. So gravity wants to pull the star ever smaller, but it's resisted by this perpetual nuclear explosion going on in the core. These stay in balance. If gravity were to win a little bit, let's say you were to temporarily stop The nuclear reaction is happening in a star.

Then gravity would start to wind, pull it even tighter. But the core of the star would get scrunched up even tighter with even higher pressures, with even higher temperatures, which would increase the reaction rate, which would make the star want to blow up a little bit more. So it reinflates. And if the fusion were to win a little bit, say you're able to temporarily ramp it up where you can get a lot of fusion going, well, that would tend to inflate the star, expand the star, which would cool it off in the core, which would lower the reaction rate, which would mean gravity would temporarily have the upper hand. And so we have a balance between the crushing gravity of the star's own weight and the energetic explosion happening because of these nuclear chain reactions. This balance is called hydrostatic equilibrium. Equilibrium because it's in balance. Hydrostatic because, well, it's not hydro. It's not water. It's gas. Static is not moving. It's just a historical term, all right? We're going to live with it.

In this case, in the case of stars, this happens all over the universe, by the way. Anytime another force resists gravitational collapse, you get what's called hydrostatic equilibrium. Why doesn't our atmosphere collapse? Hydrostatic equilibrium. How do giant clusters of galaxies maintain their shape for billions of years? Hydrostatic equilibrium. How does a star keep from collapsing into an infinitely dense point? Hydrostatic equilibrium provided by nuclear fusion. Anytime another force resists gravitational collapse, and this is usually a byproduct of the gravitational collapse itself, gravity is kind of its own worst enemy. Gets a little bit too eager, wants to collapse things into an infinitely dense point, but that leads to a condition that resists the collapse itself. So... Sorry, gravity. I mean, maybe if you're a little bit nicer, you'd get what you wanted, but you had to go all in single-mindedly and you end up with all this fusion. So stars stay in balance for a long time. It's all hunky-dory for millions or even billions of years until you run out of hydrogen in the core.

Now, you can have tons of hydrogen left over in the star everywhere else, but if it's not in the core, no fusion for you. Just like Patreon. Hey, there can be all these monies floating around the world, but unless they're put into patreon.com slash pmsutter, they're not doing anything useful or important. or vital for the perpetuation of our civilization. You know, they have to be in a very specific place. They have to be submitted to patreon.com slash pmsutter to help this show keep going. Very apt analogy. One of my best analogies ever. So you can have tons of hydrogen in the star, but if it's not in the core, it's not going to get any work done. You're not going to have any fusion. But what happens in the core? As this fusion party is happening, you're creating helium. Where does the helium go? It sinks down into the core, deeper into the core. And you can fuse helium, but in the normal everyday life of a star, it's not hot enough. The pressures aren't high enough. So it gets shoved into a little ball.

And you end up eventually, and eventually depends on the size of the star, how quickly it fuses, blah, blah, blah. The fusion, the actual hydrogen fusion, the furnace gets moved into a shell around the helium core. And how intense is nature? What's happening, it's starting to happen inside of our own sun right now. It'll take a few more billion years for it to really play out. But it's building up a core of inert, dead helium. And surrounding that, beginning to surround that, is a shell of hydrogen fusion. And it's surrounded by the ferocity of the rest of the star. Eventually, eventually, eventually... The burning of hydrogen in the shell turns off. And yes, I know it's not technically burning. It's not combustion. It's not fire. But it's called burning because it's fun to call it hydrogen burning. So it's fun. So shut up. Don't worry about that. Just call it hydrogen burning. It's the same as hydrogen fusion. It's just a name. Another historical term. Eventually, that shell runs out of gas.

It runs out of hydrogen. So gravity wins! Yay! Finally, its resistance is futile. The fusion has finally shut off once and for all, and gravity can get back to work of collapsing that star into a single, infinitely dense point. But now you have a bunch of helium in the core, and initially the helium isn't doing anything at all, just sitting there being hot. But as gravitational collapse continues and continues and continues, once the core reaches about 100 million degrees, the pressures are high enough, the temperatures are high enough, helium can start to fuse. Helium fuses? turns into carbon, oxygen, a little bit of nitrogen sometimes, and releases energy. Hydrostatic equilibrium rules the day again. But helium burning is hotter and furiouser. Why? Well, helium fusion isn't quite as efficient as hydrogen fusion. It doesn't release as much energy. So it has to really struggle to overcome gravity. This is operating at 100 billion degrees with an incredibly compressed core. To maintain that balance, the helium has to burn a lot faster than the hydrogen did.

So this phase, the helium burning phase of a star is much shorter. And the cycle is repeating again inside of massive stars. It's building up a core of unburnt, of inert carbon and oxygen. With the helium fusion happening in a shell around it, and sometimes hydrogen fusion can reignite in a shell around that, but eventually you run out of helium in the shell and gravity wins. Then carbon and oxygen can start fusing. That happens at the billion Kelvin mark. So 10 times hotter than where helium fuses, you get carbon and oxygen fusion. With a shell of helium fusion around that, a shell of hydrogen fusion, it's crazy. But then that stops because you run out of carbon and oxygen. Well, what do carbon and oxygen fuse into? They fuse into silicon. And silicon fusion ignites at around 3 billion Kelvin. And at this stage, you end up with the hottest, nastiest, seven-layer bean dip you've ever shoved your tortilla chip into. You have on the surface a skin of hydrogen. that's not doing anything. Below that, you have a skin of hydrogen that's fusing.

Below that, you have a skin of helium that's fusing. Below that, carbon that's fusing, neon that's fusing, oxygen that's fusing, silicon that's fusing. And at the very, very core, a ball of iron. That's what silicon fuses into, nickel and then iron. And as we move up the fusion chain to more and more massive elements, the energy production gets less efficient. You get less bang for your buck. fusing carbon or silicon than you do fusing helium or hydrogen. And it's at iron where the nightmare begins because it costs energy to fuse iron. When you fuse lighter elements, you gain energy. When you fuse iron and heavier elements, you lose energy. So gravity, the incredible pressure of this massive star weighing down on this core of iron, squeezes two iron bits together, but it loses air. There's nothing to fight it. There's even less resistance to gravity. So gravity pushes the attack, drives up the temperatures even more. And the fusion rate goes up even more and almost instantaneously. The star is thrown out of balance.

Some iron gets fused in this process, but most of the iron remains because this happens very quickly. That first hydrogen burning stage in a star lasts, you know, a few million years. And for small stars can last tens of billions of years. But for these big massive stars, at least eight times more massive than the sun, a couple dozen times more massive than our sun. This is over in a few million years. The helium lasts a million years. Tops. Carbon fusion goes on for 600 years. Neon burning lasts a single year. Oxygen lasts six months. Silicon fusing into iron, that takes a day. A single day. And you've run out of silicon. Then you make that ball of iron in the core. It tries to fuse, but there's nothing to stop the overwhelming gravitational collapse. Spoiler alert, gravity is going to win. But in this battle between collapse and explosion, there's going to be one big epic showdown. You have a core of iron. This core of iron is only a few miles across or kilometers across, surrounded by enough gas to fill a dozen suns, and there is nothing holding that gas back.

The iron core itself is made of protons and neutrons. And there's a bunch of electrons just hanging out, not bothering anybody. But the pressures are intense enough to shove, to literally shove those electrons into the protons. This process turns the protons into neutrons and also spits out some neutrinos. The iron, you start off with a ball of iron, it gets converted into a giant ball of neutrons, right? raw neutrons, like a gigantic citywide atomic nucleus. And the neutrons can hold themselves up from degeneracy pressure. Just like electrons, you can only fit so many electrons in a box before the box starts spilling over. You can only fit so many neutrons in a box before the neutrons start spilling over. Once this ball of neutrons is formed, this neutron core, You have the entire weight of the star, dozens of suns worth of material, that the intense gravitational pressure converted that iron core into a ball of neutrons, but it can't press it any further. It is supported. It does resist gravity.

So the entire material slams into that neutron ball and ricochets. And boom. That process, going from formation of the Iron Core to triggering the launch of a supernova, about 15 minutes. 15 minutes. This is a process that was set up millions of years in the past. And the final moments happen before this show is over. That's the initial explosion. That's the triggering of a supernova. But here's where things get tricky. We don't fully understand supernova. Welcome to, you know, science. But we've been running simulations of supernova. What's going on inside these explosions? It's complicated stuff. You know, you've got all these fusion chain reactions going on, the multiple layers, the multiple elements. You've got radiation. It's spinning. You bet there's magnetic fields. And I swear there should be a special tone every time I say magnetic field in a show. I should get a different voice like magnetic fields. Like it's the secret word of this show. There are magnetic fields happening. There are neutrinos.

Which usually no one cares about neutrinos. But what we found when we started making our initial simulations of supernovas, you know, 10, 20, 30 years ago, the shock front, the rebounding, you get this rebound off the core and then you get this shock front, this wave of explosive energy that starts propagating away to start filling out the rest of the star and make it go boom. It kind of stalls, peters out, slows down. It was thought that neutrinos might come to the rescue. Even though they don't usually interact with matter, there's enough neutrinos produced And this kind of event qualifies as enough that enough of them blow. It's like a subtle wind, a gentle wind. So there's this stalled shock front in the middle of the star. It wants to explode, but it doesn't quite have enough oomph to do it. But then there's this flood of neutrinos and kind of reinvigorates it. We thought neutrinos would do the trick, but complex simulation so that... That again, the shockwave that wants to blow up the star, the final revenge of nuclear fusion against gravity, but that peters out too.

What happens after that? We don't know. Because it's in this stage that things get really complicated really fast. In our simulations of supernova, we have a lot of trouble getting supernova to, you know, supernova. We're not exactly sure. We're pretty confident on the triggering mechanism, that this is the physics, that the iron core forms, it turns into a neutron ball, and there's a bounce and a rebound. And we know this because we've seen the neutrinos themselves. This was a major revelation back in 1987. There was a supernova that we saw. With our eyeballs, our telescopes. And we also detected this supernova using our neutrino detectors. And we actually saw the neutrinos first because the neutrinos were able to burst out of there, out of the scene, and stream straight to our eyeballs while the explosion hadn't quite happened yet. So the neutrinos actually popped out first. There was a flash of neutrinos. There's almost a supernova neutrinos first before there was a supernova of light.

And yes, I'd love to do an episode on neutrinos. Just feel free to ask. We saw the flash of neutrinos in our neutrino detector, and then we saw the flash of the explosion in our telescopes. So we knew, we know this general picture is right, but the details, what happens to actually... motivate that explosion to actually get it going, to get it through, get its second wind or its third wind to actually produce the brilliant display that we see. We think it might have something to do with unstable modes where these explosions aren't perfectly spherically symmetrical. It's not like a ball. or a shell, maybe this shock front happening inside of a star slows down, but then it starts to get unstable and starts to slosh back and forth. And then eventually one of these sloshing modes, like a resonating bridge or something just goes nuts. And that's what goes to the explosion. We're not exactly sure. And sometimes we see hints of failed supernova. Stars that get turned into neutron stars, the leftover raw cores, without having the big explosion.

We call these core collapse or type two supernova. It's the end of the line for massive stars in our universe. Just like our sun will end up as a planetary nebula and eventually a white dwarf, massive stars almost all the time end up as supernova. The core, what happens to that? It either continues on as a core in which we call it a neutron star. Sometimes it gets ripped apart and there's nothing left. It gets vaporized. And sometimes gravity wins. And in that final moment, that unrush of collapse, there is enough pressure to even overwhelm the degeneracy of neutrons. And it does tip the scale and it does get to collapse all that matter into an infinitely dense point, which is what we call a black hole. This is how black holes are formed in our universe, are through the deaths of massive stars. In these final moments, in that 10 or 15 minutes of catastrophe at the end of a life of a massive star, the amount of energy released is around, in a typical supernova like this, 10 to the 44 joules.

And if 10 to the 44 seems too abstract, that's about the same amount of energy released by the sun over its entire 10 billion year lifetime. The formation of the iron core, the fusion of the iron core takes about a day. The intense pressures converting that into a ball of neutrons takes about 15 minutes and the explosion itself takes about a couple seconds. The source of all that energy, 10 billion years of our sun's output released in those moments is gravity. Gravity drove this entire crazy train. Yeah, there was nuclear fusion and neutrinos and blah, blah, blah. But those processes were set in motion by simple gravity. The processes were driven by gravitational class, by the conversion of gravitational energy into blowing up energy. So are supernova the coolest or hottest things? I would say neither and kind of both. Supernovae obviously are not the coldest thing, taking it literally, the coldest thing in the universe, but they're not the most energetic events. The active galactic nuclei swamp them out in terms of raw energy output.

They are the most intense explosions, but they're also kind of both. You know what? It's not often that a star dies in such spectacular fashion. And when they do, 10 to 44 joules released as photons and neutrinos, you can literally see these stars blow up from the other side of the universe. Which is pretty cool. There's not a lot of things you can see from the other side of the universe. They will outshine galaxies for a couple weeks. Kind of bright. Thank you so much for listening, and especially thanks to all my Patreon contributors and the top ones, Helgi B., Justin G., Justin R., Kevin O., Michael Z., and Chrissy. For this month, who knows what the list will be next month. Go to patreon.com slash pmsutter for more info. Thank you so much for iTunes reviews. Thanks so much for asking me follow-up questions on Twitter and Facebook and on the website. I love the discussions. You can find out more about following me directly on Twitter and Facebook. My name is at Paul Matsar. Or go to YouTube.com slash Paul Matsar.

And, oh, how could I not thank the people who asked the questions at Ian Uprenea and at ThomasPatton1 on Twitter for asking these wonderful questions that led to today's episodes. And I will see you next time for more Complete Knowledge of Time and Space.