Short Wave - Could '3 Body Problem's Aliens Exist? The Science Behind Netflix's New Hit

Episode Date: July 2, 2024

Before the '3 Body Problem' became a bestselling book and a smash TV show ... it was a physics concept, with big implications for how we understand planetary orbits. In this episode, we learn about th...e science behind the screen. Plus, why it's plausible a nearby, mysterious planet could hold life.This story is part of Short Wave's Space Camp series about all the weird, wonderful things happening in the universe —check out the full series. Curious about other science behind the things you love? Email us at shortwave@npr.org.See pcm.adswizz.com for information about our collection and use of personal data for sponsorship and to manage your podcast sponsorship preferences.NPR Privacy Policy

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Starting point is 00:00:00 Just a heads up, this episode discusses the eight-part series three-body problem, and it has spoilers. We also discuss war and death, so please take care while listening. You're listening to Shortwave from NPR. Hey, Shortwaivers, Regina Barbara here. We've been in the midst of our weekly space camp series on Shortwave, but way before space camp, and actually way before I ever studied the stars, I was a lover of science fiction. And one show that really satisfies my sci-fi craving is this Netflix series that begins with a space mystery. In it, the world's leading physicists begin dying, and physics itself seems to stop working.
Starting point is 00:00:42 It was adapted from a best-selling book by Leo Sishing, translated by Ken Liu. And the first time Michael Wong encountered it, he says he was captivated by the plot, partly because of his background. He's an astrobiologist and studies planets. but partly because at the end of the day, he's just a huge science fiction lover, like me. In a nutshell, the three-body problem is basically the story of an alien invasion. The reason why the aliens are on their way to Earth is because they've evolved on a chaotic planet, one that experiences random climate extremes that causes civilizations to come and go. They basically collapse when the climate gets too hot or too cold.
Starting point is 00:01:24 And they find present-day stable Earth. Because way back in the 1970s, these aliens called the Santee make contact with the scientist. And she told them we existed. Which, okay, there are no aliens in real life that we know of, but there is a lot of other stuff the book gets right, which is a big reason for Mike's love as a scientist and a sci-fi lover. For instance, the Santee are traveling from a star system four light years away.
Starting point is 00:01:54 they're going at 1% the speed of light, and so it takes them 400 years to get from their homeworlds to Earth. And that's a really important plot point. And it's also very realistic. There's no warp speed or hyper speed. And the TV show has actually improved on the realism of the story in some ways, like how it highlighted all the collaboration across expertise and backgrounds that happens in science. I love that the producers split one main character from the books into five different characters for the show.
Starting point is 00:02:23 I think this is a great choice from just a production point of view. But for me, it's so important because this really fights against the lone genius stereotype in science, where you just have this one solitary person who can figure it out all on their own. And here's the thing. Even the name of the TV series and the first book is also a reference to real-life science. In physics, any object that feels forces is called a body. And the three-body problem is a real scientific concept. one that tries to explain the massively complicated orbits of three bodies in space.
Starting point is 00:02:55 So today on the show, the three-body problem, how science is portrayed in the novel and the hit TV show, what real-life scientists have to say about it. Plus, if aliens are out there, is it even ethical for us to try to contact them? I'm Regina Barber, and you're listening to Shortwave, the science podcast from NPO. Okay, Mike, before we go deeper into the series, let's start with some basic physics explainers here, okay? because the orbit of two objects pulling on each other, it's fairly stable, right? So scientists have been able to predict those kinds of orbits very accurately for hundreds of years. I did this in, you know, undergrad.
Starting point is 00:03:38 And this is the basic concept we need to understand before we get into this whole like three body problem and how it complicates things. Yeah. So any object with mass, you know, will exert a gravitational force on other objects in the vicinity. And so starting simply, just imagine two objects with mass, maybe like the sun and the earth. Earth, and they're both tugging on each other. The sun's tug on the Earth, obviously, that makes the Earth swing around the sun in a roughly circular orbit. That's, you know, why we have years, and we go around this beautiful star of ours. But the Earth also tugs a little bit on the sun, and that causes the sun to wobble just a little bit in space. Yeah, that's how we
Starting point is 00:04:19 know that there's other planets around other stars, because they wobble a little bit. When I learned that, I was, like, blown away. Exactly. Yeah, we detect those little, little tiny wobbles of stars, and we infer then that there are planets that tug on those stars, even though we don't see those planets at all, or in most cases we don't see those planets. So that's the two-body problem, like two objects pulling on one another, two bodies, easy. Right. So for the two-body problem, like between a planet and a star, you get very stable, very periodic, very regular solutions. But if you have three, you just throw one more gravitating object into the mix, all of a sudden, you don't get this beautiful, simple,
Starting point is 00:04:58 general solution anymore. The system becomes chaotic, so even a tiny little deviation can cause huge changes down the road. Okay, and that chaos, that's what causes the three-body problem, which, like, is famously hard to solve. So in astrophysics, the three-body problem describes the question of how you predict the motions of... of three mutually gravitating astronomical objects, three bodies, all with gravitational poles on each other, causes a chaotic system that can then be very difficult to predict the exact motion of.
Starting point is 00:05:37 And so it makes it really difficult to predict the ultimate motions, you know, thousands, tens of thousands, millions of years in the future for three mutually gravitating objects. And so the only way to make this prediction is to, integrate numerically, which means to go step by step, you know, inch forward in time, calculate the little bit of change in the positions and the velocities of each of the three bodies incrementally and then do that calculation over and over and over again. And actually, this relates to a scene that we saw in the Netflix series where one of the solutions
Starting point is 00:06:13 in the video game that they're playing that was proposed by some other players involved basically building a human computer with these armies of people doing binary calculations. Yes. And that's actually exactly what we have to do to solve the three-body problem, except we don't use human computers. We use supercomputers. But there's no, like, solution that you can just write pen and paper the way you can, you know, write the equation for a circular orbit
Starting point is 00:06:46 or even an elliptical orbit around a star for a single planet. When you have three bodies, you have to do basically this grunt work of integrating bit by bit by bit to predict that future. Wait, okay, so just to clarify, so for instance, when we have our own solar system, we have the sun and we have lots of bodies, right? We have Jupiter. We have, you know, Mars, we have Earth. We have eight planets.
Starting point is 00:07:14 So how come that doesn't create like a nine body problem? Yeah, yeah. So basically, you know, the sun dominates the gravity of our star system. And so, you know, although Earth does get pulled by the other planets, like Jupiter, and Saturn, it's very minute compared to what the gravity from the sun is doing. So basically, think about the system of stars in the three-body problem, where you have three stars in a very chaotic orbit. If you imagined yourself as a planet around that triple star system, where the gravitational
Starting point is 00:07:51 field at your planet is always changing because of the configurations of the three stars that you're orbiting, that's just going to wreck havoc. on the amount of insulation that your planet is going to have, the amount of starlight that is being received. And that will definitely cause very chaotic climates. Yeah, I mean, I think a good example is like why we have seasons. We have this tilt on the earth. That tilt makes it so you get more sunlight during the summer
Starting point is 00:08:17 and you get less during the winter. So that affects your climate. So just imagine not just more sunlight, but like the star is closer to you. And you're getting even more energy or you're getting none. And it must be just, yeah. Yeah, that's why they're leaving. Right, exactly.
Starting point is 00:08:33 And with three stars, you know, sometimes they're all up in the sky at the same time, and you just burn to a crisp. And, yeah, that's going to create huge climatological changes. Okay, so the premise is actually kind of realistic, which is awesome. And the alien civilization, which is fictional, comes from this star system that is real, Alpha Centauri. Yeah, so there actually is a triple star system for light years. from Earth. And we call this star system
Starting point is 00:09:03 the Alpha Centauri system. It's comprised of three stars, Alpha Centauri, A, B, and C. But C is often called Proxima Centauri because it's actually the closest to us. And orbiting Proxima Centauri is a planet that we think might be habitable. That is, it's probably roughly the size and mass of the Earth
Starting point is 00:09:26 and it's in the Goldilocks zone around that star, meaning that it receives the right amount of starlight to potentially maintain liquid water on its surface. And it's just really amazing to think that, yeah, there's actually a habitable world that may have an alien civilization on it for all we know just four light years away. So you're saying we don't know if it's habitable and we don't really know too much about this exoplanet, right? Just like its location. Yeah, that's right. So in order to figure out if it's habitable or indeed inhabited with life, life, we'll need to know more about the chemical makeup of this planet and know more about
Starting point is 00:10:06 its surface conditions and understand if it has an atmosphere, because the atmosphere is what it keeps Earth habitable. We don't know if this planet has an atmosphere. We don't know what its surface is made of, if it has oceans or continents or it's just a bare rock. And we really don't have a good handle on what its chemistry is. This is because we're only inferring the existence of the planet through its gravitational influence on its host star. Yeah, we haven't imaged or anything.
Starting point is 00:10:34 Exactly. We'll probably need to build a next generation telescope to be able to do this for terrestrial-sized worlds, rocky worlds, the size of Earth, like Proximus Centauri B. Because we just don't have telescopes that can do that right now. But could I just mention one more thing about Proxima Centauri B? Yes, absolutely. I think it's very important to just make the distinction between the real life Proxima Centauri B and the planet that is portrayed in the three-body problem. Yeah. Proxima Centauri B is not in a chaotic orbit.
Starting point is 00:11:06 It's not going to leave Proxima Centauri and then go orbit the other two stars for a little bit and then like swing back out, you know, it's actually quite stable. So don't be scared. Right, exactly. The Sonti are not coming for us, probably. Yeah. Okay. I mean, this is like a really good transition to like, you know, people and society and ethics, right?
Starting point is 00:11:30 Like, I'm watching the show and I'm thinking like, should we reach out to other life forms outside of Earth, right? Like, what's the ethics of contacting aliens in the first place? Oh, wow. Yeah, this is a hotly debated topic in the astrobiology community, this idea of messaging extraterrestrial. intelligence or METI, which is generally just projecting ourselves into the cosmos, being that sort of like beacon saying, hey, we're here, hey, we exist. Just like the show. Exactly.
Starting point is 00:12:03 Just like the show. Right. And a lot of people kind of get very worried about that because, again, we're a very young planetary civilization. humankind has not been on planet Earth for that long, geologically speaking, evolutionarily speaking. And so the kinds of alien civilizations that might be listening to us are likely to be a lot older and hence probably a lot more advanced than we are. So is letting a more advanced civilization know about our presence necessarily the best idea?
Starting point is 00:12:36 You know, there's always that worry that we're inviting a bunch of existential risk. On the other hand, academics have argued that if there are super advanced extraterrestrial civil out there, they already know we're here. They can already observe our presence on planet Earth. Maybe messaging is not alerting them, you know, that we're here because they already know that we're here. And if they already know that we're here and they haven't conquered us yet, then maybe they're friendly. Maybe we're good. Maybe we're good. Yeah. Thank you so much, Mike, for talking to me about this, you know, this book, this series. I love sci-fi. And I know you do too. So thank you. Thanks so much for having me. This was a blast.
Starting point is 00:13:20 Before we head out, a reminder that we'll be back tomorrow with our regular shortwave and back Tuesday with our next installment of the space camp series as the Starship shortwave, that's you and me, continues further and earlier into space time and deepens our understanding of the universe. And I have this sneak preview from one of our experts. Hi, Shortwave Space Cadets. It's Priyana Rajan, your admiral of the ocean of darkness. While you're out there in space, why not get your net out and fish for some dark matter to bring back to Earth? That way, we can study it and figure out what it is.
Starting point is 00:13:55 I'll be eagerly awaiting your samples. As you know, this is a big unsolved question in cosmology. This episode was produced and fact-checked by Hannah Chin. It was edited by our showrunner Rebecca Ramirez, and the engineer was Cui Lee. Julia Carney is our space camp project manager. Beth Donovan is our senior director and Colin Campbell, is our Senior Vice President of Podcasting Strategy. Special thanks to our friends at the U.S. Space and Rocket Center, home of space camp.
Starting point is 00:14:24 I'm Regina Barber, and you're listening to Shortwave from NPR.

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