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  • Thanks to CuriosityStream for supporting this episode!

  • Go to CuriosityStream.com/Space to learn more.

  • [♪ INTRO]

  • The star-mapping satellite Gaia has been scanning the sky for five years now,

  • building a catalog that should reach one billion stars.

  • Given all that data, it makes sense that Gaia has found some weird stuff.

  • And in the middle of it all, astronomers have singled out over 20 stars

  • speeding across the Milky Way toward intergalactic space.

  • And stars don't usually do this!

  • The galaxy has a lot of gravity to keep stuff in.

  • But there are a few things that can slingshot a star out of a galaxy.

  • And whatever the case, it takes some extreme gravitational interactions.

  • Normal stars travel around the galaxy at a casual 1 million kilometers an hour or so.

  • But some of the fastest stars making their escape are moving over three times as fast,

  • and many of them seem to be coming from the same place: the center of our galaxy.

  • Sitting there, keeping everything glued together,

  • is a supermassive black hole called Sagittarius A*, or Sag A* for short.

  • It's surrounded by a huge, dense region of star formation.

  • With such extreme gravity keeping all the gases nice and compact,

  • some of those gases condense and ignite to become stars.

  • So you get a lot of stars forming close together, and that means you end up with lots of pairs

  • or groups of stars orbiting each other while they also circle Sag A*.

  • So let's take the case of a binary star system going around the black hole.

  • If they're too close to the black hole to have a stable orbit,

  • the stars will spiral inward toward it.

  • And at a certain point, the black hole's gravity

  • will overcome the gravitational bond between the two stars and pull them apart.

  • The innermost star will be swept into a tighter orbit around the black hole, pulled away from its companion.

  • But here's the thing, those two stars orbiting each other have a ton of energy between them.

  • There's kinetic energy in their orbital motion and potential energy in their gravitational bond.

  • So when half of that system disappears, the energy doesn't disappear with it.

  • Because energy in a system is always conserved!

  • So when its partner leaves that binary star system and gets captured by the black hole,

  • the remaining star suddenly gets all that energy, which gives it a giant kick across the galaxy.

  • This process is an example of what's called dynamical ejection.

  • But only about half of the galaxy's fastest-moving stars are coming from the center,

  • so they can't all be survivors of the black hole.

  • There has to be something else going on to explain how all those other stars got moving so fast.

  • And it looks like there is.

  • It starts with a Sun-like star in a binary system with a gigantic companion.

  • These systems can exist anywhere in the galaxy.

  • And one day, the huge companion star explodes into a supernova.

  • To understand what happens next, imagine a ball on a string: you're holding one end

  • and whirling the ball around over your head.

  • And then the string breaks.

  • The ball sails off in a straight line.

  • And the faster you're whirling it around, the faster it flies off.

  • And that's exactly what happens to the smaller companion star.

  • Before the explosion, there's a gravitational bond between the two stars

  • that holds them together like a string.

  • When one star bursts into a supernova, its mass gets scattered into space.

  • That essentiallybreaks the stringof the gravitational bond.

  • Without any mass tying it down, the remaining star goes sailing toward interstellar space,

  • moving as fast as it used to orbit its old companion.

  • This is called binary ejection.

  • And binary ejection probably accounts for most of the smaller, older stars that are

  • on their way out of the galaxy.

  • So that explains most of the stars that are leaving the galaxy.

  • But it still can't explain everything.

  • So, finally, one last mechanism for slingshotting a star.

  • This one is another type of dynamical ejection, but it doesn't happen in the center of the galaxy.

  • Instead, it seems to happen when a star is booted out of its star cluster.

  • That can happen sometimes, because, in a dense cluster,

  • stars are getting pulled around on all sides by the gravity of their neighbors,

  • and everything is exchanging a lot of energy.

  • For instance, a star might swing close to a binary pair and get swept up in a chaotic 3-body orbit.

  • It might split off with one member of the pair, or the stars might all end up as single stars.

  • In the process, a lot of energy gets traded around, and under just the right conditions,

  • a star can pick up enough energy to get kicked out of the cluster.

  • Astronomers discovered an extreme example of this phenomenon in 2014,

  • when they found a star eight times as big as the Sun traveling about twice as fast as other stars in the galaxy.

  • Hurling such a massive star across the galaxy at that speed takes serious energy.

  • And astronomers think it got ejected from a really dense star cluster.

  • This star was an outlier because of its size, but ejections like this happen on smaller scales pretty often,

  • and they're probably behind many of the other stars speeding across the galaxy.

  • The fact that these extreme gravitational interactions are relatively common in our galaxy

  • suggests that there are lots of rogue stars flying through intergalactic space,

  • booted from their home galaxies.

  • Fortunately, Gaia and other surveys are still gathering tons of good data,

  • so we'll probably see plenty more weird stuff soon!

  • If you're interested in learning more about some of the most extreme gravitational interactions in our universe,

  • you might like the CuriosityStream documentaryKnowing Without Seeing.”

  • It's all about black holes and how the more scientists learn about them,

  • the more mysteries they open up.

  • And if science documentaries are your thing,

  • CuriosityStream has over 2,400 of them for you to explore, including exclusive originals.

  • They cover a whole range of topics, including science, nature, history, technology, and others.

  • You can get unlimited access for as little as $2.99 a month, and since you're a SciShow viewer,

  • you can get the first month free if you sign up at curiositystream.com/space and

  • use the promo codespace.”

  • [♪ OUTRO]

Thanks to CuriosityStream for supporting this episode!

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B2 中高級

彈弓打星的3種方法 (3 Ways to Slingshot a Star)

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    林宜悉 發佈於 2021 年 01 月 14 日
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