Placeholder Image

字幕列表 影片播放

  • [ ♪ Intro ]

  • Around 1910, two small-but-mighty experiments popped up in the scientific literature.

  • The first was from a physicist named Domenico Pacini in 1911.

  • He sent instruments underwater and measured radiation levels at different depths.

  • The second came from another physicist named Victor Hess.

  • In 1912, he jumped in a hot air balloon and traveled about five kilometers above Central Europe

  • to measure the radiation way up there.

  • These experiments might seem like standard data-collecting stuff,

  • but they helped reveal something that would change the way we understand the universe.

  • See, about ten years earlier, scientists had detected a very low level of radiation in the air.

  • Originally, they assumed it came from rocks,

  • but Pacini and Hess showed them that they were wrong.

  • They found that there was more radiation at higher altitudes and less lower down.

  • And that meant the radiation couldn't just come from the Earth.

  • Some of it had to be coming from space.

  • Eventually, this kind of radiation became known as cosmic rays.

  • Today, it's mostly used to understand the objects that produce it,

  • but in the early 1900s, it had a different job:

  • It helped us discover brand-new subatomic particles

  • long before today's accelerators were a glimmer in any physicist's eye.

  • So in a way, all those experiments underwater and in balloons didn't just help us find some space radiation:

  • They helped found modern particle physics.

  • After we first discovered them, it took decades to figure out what cosmic rays were.

  • But today, we know they're charged particles that are constantly hitting Earth

  • at nearly the speed of light.

  • They're mostly made of individual protons,

  • but have a few electrons and larger atomic nuclei every once in a while, too.

  • And while some come straight from the Sun, most are from big, destructive things,

  • like supernovas or stars falling into black holes.

  • Recently, astronomers have used these rays to learn about these extreme environments,

  • but many scientists in the early and mid-1900s weren't really focused on the rays themselves.

  • Instead, they studied what happened when cosmic rays reached Earth.

  • And we're glad they did, because these rays ended up being one of our most important early

  • tools for studying the universe.

  • Since cosmic rays move very close to the speed of light, they carry a lot of energy.

  • When they hit things, that collision is so powerful that the energy itself can turn into subatomic particles.

  • The idea that energy and matter are interchangeable is actually the whole point of “E = m c-squared,”

  • so theenergy becoming particlesthing isn't game-breaking.

  • But it was game changing, because some of the particles that popped up in those cosmic ray collisions

  • were things we had never seen before.

  • In the early 1900s, scientists were able to study them in devices called cloud chambers,

  • where water or alcohol vapor condensed into a cloud around anything that passed through it.

  • They watched how the particles moved in these chambers, and then they could use that data

  • to figure out their properties.

  • For instance, if the cloud chamber sat in a magnetic field,

  • electrically-charged particles would make curved paths,

  • and the shape and length of that path would reveal things

  • like the particle's speed, mass, and how long it lived.

  • Which sounds like magic, but it's really a pretty straightforward research method

  • and it revealed so much.

  • In 1932, for example, a postdoctoral researcher named Carl Anderson

  • was using these sorts of methods to watch cosmic rays hit a lead plate.

  • He found that the particles coming out of his collisions had the same properties as electrons,

  • except that they had the opposite electric charge.

  • They had a positive charge instead of the usual negative one,

  • but everything else seemed weirdly the same.

  • As it turned out, Anderson had discovered positrons and the first kind of antimatter ever observed.

  • All matter has an antimatter counterpart, so Anderson effectively doubled the number

  • of known particles with a single discovery.

  • And if you know anyone who's ever had a Positron Emission Tomography, or PET scan,

  • you can thank Carl Anderson.

  • But that wasn't his last cosmic ray discovery.

  • A few years later, he and others found another key particle: the muon.

  • It's a heavier version of the electron and in the eighty years since this discovery,

  • scientists have used muons to conduct hundreds of tests of Einstein's theory of special relativity,

  • the theory that talks about how things behave when they're going really fast.

  • We use Einstein's ideas to understand the universe, so making sure he was actually right

  • is kind of important.

  • And muons help with that.

  • But in the 1940s, the most important thing about muons was that they existed.

  • Physicists had predicted there'd be positrons a few years before their discovery.

  • But no one thought there'd be heavy electrons out there.

  • They were completely unexpected.

  • And the closer physicists watched cosmic ray collisions,

  • the more of these sorts of surprises popped up.

  • They even put scientists on a path that would lead to the discovery of quarks,

  • the tiny building blocks that make up things like protons and neutrons.

  • Ultimately, the torrent of discoveries coming out cosmic ray research was amazing.

  • Like, who would have thought that space radiation would turn out to be such an accessible way

  • to understand the subatomic world?

  • But also, all these discoveries kind of sent everyone scrambling.

  • So many things were being discovered that particle physics,

  • which was now becoming a proper scientific field, was in chaos.

  • Nobody knew how all these pieces fit together,

  • and scientists were often unsure if what they were seeing was something completely new,

  • or was just a known particle acting in a different way.

  • To make things more complicated, cosmic rays aren't exactly reliable.

  • They're free and powerful, and you can't control how often they come into your chamber,

  • or how strong they'll be.

  • And if physics needs anything, it's a lot of consistent data.

  • Eventually, this led researchers to start building particle accelerators to test their ideas.

  • And by the 1960s, they were mostly moving on from cosmic rays.

  • Although we still use this radiation for other studies,

  • this was the end of kind of a sweet chapter in physics.

  • This space radiation let us see a universe that had been completely hidden from us.

  • Thanks for watching this episode of Scishow Space

  • which we couldn't make without our Patrons on Patreon.

  • If you want to learn more, go to Patreon.com/SciShow

  • [ ♪ Outro ]

[ ♪ Intro ]

字幕與單字

單字即點即查 點擊單字可以查詢單字解釋

B2 中高級

宇宙射線和氣球是如何開始粒子物理的? (How Cosmic Rays and Balloons Started Particle Physics)

  • 5 0
    林宜悉 發佈於 2021 年 01 月 14 日
影片單字