Short Wave - Behold! The Dulcet Tones Of Cosmic Rays

Episode Date: June 7, 2023

Teppei Katori loves two things: particle physics and music. Naturally, he combined the two. Today on Short Wave, Teppei talks to host Regina G. Barber about how he and his collaborators convert data f...rom cosmic rays—high energy particles from space that are constantly colliding with Earth—into beautiful sights and sounds. 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 You're listening to Shortwave from NPR. Tepe Katori was always amazed by the natural world and with breaking it down. It started with objects in nature, flowers and birdwatching, and an obsession with knowing their names. I love to memorize the name of the flower on the street. As he grew older, he started breaking down his natural world into smaller and smaller components. You can go all the way down to the quark and the leptone. and yeah, I found, wow, it's really fascinating. Quarks and leptons, some of these subatomic particles that combine to form everything we all,
Starting point is 00:00:37 you, me, Tepe, interact with. Thus began Tepe's journey to become a particle physicist, to study the world in the smallest components known to humankind. It's a journey that would eventually take him to different continents as he continued his studies. I came to the point, like, man, like, even I know, like, all the name of the flower in Japan, maybe I can't talk people in the rest of the world because maybe there's a different name in America. And the United States is one of those far-flung places he went to.
Starting point is 00:01:08 He got a PhD in high-energy physics from Indiana University Bloomington. Then he headed to Illinois to study neutrinos at the U.S. Department of Energy's Fermi National Accelerator Laboratory, or Fermi Lab. But outside his particle physics work in the lab, Tepe ventured into the city, looking for community. Yeah, I met a lot of people in Chicago just walking around. I was looking for something new, I guess. Eventually, Tepe started meeting different people, artists and musicians who lived in his neighborhood, or the surrounding areas of Wicker Park. He'd see people just walking around, going to and from pubs, and he'd fall into conversation with them about their work. Some of them play music, just go walk in and there's art night.
Starting point is 00:01:53 And, yeah, I liked it. And they met lots of people. People who inspired Tepe to connect with his creativity. He would become a particle physicist by day and an artist by night. Playing music in a street band and creating art exhibits that connect us, macroscopic beings, to the subatomic realm. Today on the show, Connection. How a particle physicist blends science and the arts to create a whole greater than the sum of its parts.
Starting point is 00:02:20 And to help people feel the subatomic building blocks of the universe. I'm Regina Barber and you're listening to Short. wave from NPR. For Tepe, the magic of combining arts and physics came when he was a postdoc. That's when he came across environmental encroachment. They're traveling brass street band. Tepe remembers them breaking out into loud brass numbers, like the one you're hearing now. And it overwhelmed the sidewalks, poured out onto the streets, and sometimes attracted throngs of followers.
Starting point is 00:02:56 Tepe became obsessed. And I followed them, and then at some point, why don't you, you know, play music. And then I start to play music. And never played brass music before. So it's from zero. They asked Tepe to play trombone for them. And he picked it up quickly.
Starting point is 00:03:14 Then he started touring with them, playing trombone while working at Fermilab. And it was through environmental encroachment and the rest of the scene that he first started thinking about how he can combine his passions for physics, music, and art. Tepe eventually collaborated with his art friends
Starting point is 00:03:30 on some science-inspired art show. And he says art and physics are more similar than you might think. Artists can create with no set end goal. It's the same with particle physics, really. Lots of things we do, we don't really expect, like, outcomes. Because we are looking for something new. And in this sense, art has a same attitude, and I find it's very cool. There was a particularly interesting data set from an underground lab
Starting point is 00:03:59 where scientists are searching for invisible particles, called neutrinos. So neutrino is a particle, like atom, but it's a subatomic, and it's not only small as an atom, it's the tiniest, like a most fundamental block of the particle. There are many different kinds of fundamental particles. Some carry a force like photons,
Starting point is 00:04:22 which carry the electromagnetic force and form visible light. Some of them carry mass, and some combine to form different components of atoms. you know, like protons and neutrons, which are made up of particles called quarks. So the atom is made by nucleus and electrons, and the nucleus is made by proton and neutron, and the proton and neutron is made by quarks, which is just two quarks, up quark and down quark. So like up quark and down quark and electrons can produce all matter in the universe. neutrinos are another fundamental particle, but they're much harder to find.
Starting point is 00:05:01 There are so many neutrinos floating around, but you don't really touch or anything, because most of the neutrinos just pass through your body. So neutrino is famous for this feature that means it's barely interact and just passing through anything. Neutrinos have a nickname, ghost particles. It's like a ghost, you know. It's everywhere and you can't really interact. So if they barely interact with matter, if they're just running through us at all times, how do we, as humans, scientists, how do we detect them? You need a lot of neutrino.
Starting point is 00:05:35 And there are lots of neutrinos from the sun and from the atmosphere. But the problem, yes, to see them, you need a detector. But most of the neutrinos just penetrate and pass through without any trace. If you wait long enough, maybe some lucky one interact. and produce some other particle, since it's rare, you need a big detector. So, neutrino detector is often like a big, you know, volume of something, like a big water, tank, things like that, to maximize the chance of neutrino interact something else.
Starting point is 00:06:11 And these are the experiment looking for neutrinos coming from extra-galactic object. So neutrino coming from really, really far away and really, very, very high energy. His latest project is a collaboration with a friend he met, his days in environmental encroachment. Artist and musician Christo Squire, who's also an artist and resident at King's College London, where Tepe teaches. We know each other many years.
Starting point is 00:06:35 We met in the music festival first time. It's also the music festival both his band and my band play. Christo and Tepe brainstormed how to use all this data, from the hunt for neutrinos and the much more common cosmic rays, which are mostly high-energy protons moving really, really fast.
Starting point is 00:06:53 They landed on an art installation that would translate particle physics data into sound for a concert series, something that would make the invisible, the ghost-like, feel real. So we have this idea to use some of the cosmic ray detector for things, but more for music directions. Because in the end, we tried to compose this cosmic ray-inspired, neutrino-inspired music. They decided to use live data from the super K detector. It's a big detector buried 3,300 feet below a mountain in Japan, Mount Ekeno, and turn it into one big musical instrument. The superké has huge neutrino detection pools, and when a neutrino is found, the detector produces a little light signal. These light signals became the basis of their instrument. They divided the detector into seven parts, with each part corresponding to a note on the musical scale.
Starting point is 00:07:50 Then, depending on where the light signal came from, from, they would produce different musical notes. Notes at the bottom of the detector were assigned a lower octave and notes at the top were assigned a higher octave. So, Crystal was quite interesting in this randomness. Because when the neutrino comes in and light is produced and these are detected by each detector, but these all process is not like smooth, like, poop-pap-pup-pup-pah, you know, like. So you can come up some nice, you know, music.
Starting point is 00:08:23 and way to interpret this phenomenon. So that's one type of music. They called this first musical attempt Subatomic. At a concert hall on the banks of the River Alt, a group of musicians gathered to translate the supercase data into sound. It was a blend of improvised and composed music based on the detector's past results. In their next installation, they turned Subatomic
Starting point is 00:08:53 into an interactive art installation called Particle Shrine. Tepe says that he and Christo hoped the art installation would help people appreciate the presence of subatomic particles. Because we don't see it, but it's everywhere, and it's kind of fascinating. In a physical space, people could experience the passing particles as light, as well as sound. So the light and light change the color when the cosmic waves pass through. Oh, and also a floor is a projection of neutrino data from Super Kamokandeo Kameo Kande. and people love to sit there and just watch.
Starting point is 00:09:36 For Tepe, this work only enhances his research in particle physics. For once he's not focused on how or when or why these particles are passing through you, the more important thing is that you feel it. I don't have to explain it, but this space tells you that a cosmic ray passing through your body and you can feel it. You want to be able to have people feel cosmic growth. not just have to be explained to them. It's like in all art, right?
Starting point is 00:10:11 You want to show, not tell. Yeah, because it's a, you know, and it's unfortunate, right? Because it's everywhere, and it's so easy for you not to know any of this, and you die, right? But once you know it, you know, the life is way more beautiful,
Starting point is 00:10:28 which is exactly like physics. If you know the physics, you know how the things works and the life is more beautiful. So, yeah, same. things, cosmic gray, you know, the flower on the street. You know, if you know it, it makes more beautiful. Thank you so much for taking the time to talk to us. This was wonderful. Oh, thank you for having me. Yeah. Tepe and Christo's installation Particle Shrine was originally unveiled
Starting point is 00:10:59 at Science Gallery in London. They have a new show coming this month at the Somerset House as part of the London Design B&L. And they'll be in the UK in September as part of the Hidden Notes Festival. This episode was produced by Margaret Serino and Burley McCoy, edited by our managing producer Rebecca Ramirez, and fact-checked by Jane Gilvin. Our audio engineer was Robert Rodriguez. Beth Donovan is our senior director of programming, and Anya Grunman is our senior vice president of programming. I'm Regina Barber. Thanks for listening to Shortwave from NPR.

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