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  • [♪ INTRO]

  • At first glance, the universe can seem pretty straightforward, like when it comes to dying stars.

  • According to the standard story, which matches most of what we see around us,

  • small stars die relatively quietly, while big ones explode as supernovas.

  • But while that sounds neat and tidy and all, the reality is, big stars are complicated.

  • In the last two weeks, a pair of papers in the journal Nature

  • has helped us address two outstanding mysteries about these stellar giants:

  • how they really die, and how big they can actually get.

  • Both papers remind us that, for as nice as it would be to have one clean set of rules

  • to explain space, things aren't always that easy. But they are way more interesting.

  • The first paper was on hypernovas.

  • Kind of like some regular supernovas, hypernovas can form when a star's core collapses really quickly.

  • But while supernovas form from stars a few times more massive than the Sun,

  • hypernovas form from stars tens of times as massive.

  • That makes them much brighter,

  • and they've produced some of the biggest explosions since the Big Bang.

  • But there's also a lot we don't understand about them.

  • For example, according to models, the gas near the star's poles

  • should produce huge jets of radiation known as gamma-ray bursts, or GRBs.

  • Sometimes, we do see this happen.

  • But we've also seen hypernovas without these bursts, and it's not super clear what's going on.

  • Previous work has suggested this could be thanks to what's called a cocoon:

  • a cloud of gas near a star's pole that's heated by a jet of GRB radiation.

  • Scientists hypothesize that some jets can punch through these cocoons,

  • but others get absorbed and never make it out, which explains the missing gamma-rays.

  • The problem is, cocoons are notoriously hard to study, either because they're outshined

  • by the GRB itself, or because we don't notice them in time.

  • So it's hard to figure out how true this hypothesis is, or to investigate it further.

  • That is where this new paper comes in.

  • By studying a special hypernova observed in 2017,

  • authors were able to look at this process in more detail than ever before.

  • Their hypernova was special because it involved a pretty dim GRB.

  • It was bright enough to detect, but it wasn't bright enough to outshine the cocoon,

  • and that allowed the team to study the explosion within a day of it happening.

  • That turned out to be really helpful.

  • For one thing, the results back up what we used to think about cocoons.

  • In a model of their hypernova, the team saw the jet lost some of its energy to the gas, but not all of it.

  • If it had been stronger, it probably would have punched all the way through.

  • And if it had been weaker, it would likely have been absorbed,

  • just like previous studies said would happen.

  • Also, by analyzing the light from around the explosion, the team was able to tell us more

  • about what these cocoons are actually like.

  • They discovered that the gas was moving, like, almost ridiculously fast: Some materials were

  • going up to a third the speed of light, which is faster than anything we've seen in similar explosions.

  • The gas also contained different elements during the first day of explosion than later on,

  • things like iron, cobalt, and nickel.

  • One researcher suggested these elements were probably produced in the star's core as it collapsed.

  • That means that, not only can studying cocoons tell us how these explosions work,

  • but they can also tell us what it's like inside of them.

  • And the best part?

  • The researchers collected a ton of data, so there might be even more to learn.

  • But either way, this is a big step in the process of understanding how big stars die,

  • and it has some researchers pretty excited.

  • Of course, hypernovas, and the stars that cause them, can only get so big.

  • That's because if too much gas falls together as a star is forming,

  • the gas will heat up and push more gas away.

  • That generally stops stars from getting much heavier than a couple hundred times the Sun's mass.

  • But that also poses a problem.

  • See, early galaxies had supermassive black holes at the center, just like today's galaxies do,

  • that could have been millions or billions of times the Sun's mass.

  • But black holes generally form from dying stars,

  • and then they grow when gas or stars fall into them.

  • So if early supermassive black holes were formed from stars only a couple hundred times

  • the Sun's mass, there wouldn't have been enough time for them to get so big.

  • Fortunately, a paper published this Wednesday is challenging some of those assumptions,

  • by saying that the early universe totally could have produced stars that weren't just

  • a measly hundred or so solar masses.

  • They could have been ten thousand solar masses.

  • To figure this out, the paper's authors simulated giant gas clouds starting about

  • 200 million years after the Big Bang.

  • As the clouds crashed into each other, they condensed into lots of different stars.

  • But the biggest stars didn't form in the center of the action with the others.

  • They were out in, like, the countryside, or, at least the suburbs.

  • There, they could keep growing as gas clouds merged together,

  • but their heat didn't get added to the heat from the other stars.

  • The more heat there is, the more pressure there is to push the extra gas away,

  • so by staying out of that crowded environment, these stars could get huge.

  • Admittedly, these enormous stars were pretty rare, only two formed out of hundreds of cases,

  • but that's still common enough to make supermassive black holes much less mysterious.

  • And thanks to research from the last few years, the team can even explain why we haven't

  • seen enormous hypernovas from these giants.

  • Some extremely massive stars can skip the supernova entirely and collapse straight into

  • black holes at the end of their lives.

  • Other research has even suggested that big collections of gas could fall together

  • in just the right way to skip the star stage, too.

  • They'd go straight from gas cloud to black hole.

  • The new simulations didn't get into whether either of these scenarios happened to the first monster stars.

  • But they do give us a pathway going from hydrogen to enormous black holes,

  • which is exactly what we need if we're going to understand the earliest galaxies.

  • Thanks for watching this episode of SciShow Space, which is officially

  • our 500th episode on this channel!

  • We started SciShow Space back in 2014, and we have loved getting to explore all of the

  • mystery, discovery, and straight-up ridiculousness of the universe with you over the last five years.

  • If you want to help us make our next 500 videos, you can check out patreon.com/scishow.

  • And if you want to keep learning about space with us, and your place in it,

  • just go to youtube.com/scishowspace to subscribe.

  • [♪ OUTRO]

[♪ INTRO]

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巨人の星はルールを守らない|サイゾーウーマンニュース (Giant Stars Don't Follow the Rules | SciShow News)

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    林宜悉 に公開 2021 年 01 月 14 日
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