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  • [ ♪ Intro ]

  • On Monday, a paper came out in the journal Physical Review Letters

  • that describes what may be the strongest material in the universe.

  • It's called nuclear pasta.

  • It's found inside neutron stars:

  • the supermassive, dense remains of stars that have gone supernova.

  • They are, in fact, made mostly of neutrons.

  • We've known about nuclear pasta for a while,

  • but we haven't really understood its properties until now.

  • And while it probably won't be the next big building material,

  • it could help astronomers understand how neutron stars behave.

  • In general, neutron stars are pretty wild objects!

  • And so as a result, their anatomy is also pretty wild.

  • For one, they have brittle crusts, which we've known about since the early 1970s,

  • shortly after these stars were discovered.

  • The crust formed by neutrons that are forced into a crystal lattice by the star's extreme gravity.

  • A pretty cool consequence of that brittleness is that the crusts break if put under enough strain.

  • And crust breaking can cause all kinds of behavior,

  • like an increase in rotational speed, and magnetic outbursts.

  • Just beneath that outer crust lies the nuclear pasta, which was first proposed in the 1980s.

  • This material is formed when, at high pressures,

  • the star's neutrons and any surviving protons are compressed so much

  • that they start organizing themselves into some really odd structures.

  • For example, they form these long strings, called spaghetti,

  • and these board-like shapes, called lasagna.

  • And for the record, those are both the technical terms!

  • Scientists are great.

  • For a long time, though, we've really had no idea what it meant for neutron stars to have nuclear pasta.

  • Apart from the weird shapes and the general composition,

  • we didn't know much about its characteristics.

  • Like, if the crust can break, can the pasta?

  • In an effort to figure out what was going on down there,

  • a team from McGill University, Indiana University, and Caltech

  • ran the largest supercomputer simulations of this material.

  • They tested it under all kinds of stretching and strain, trying to get it to break.

  • And it turns out it needed a lot of strain.

  • Like, more than it would take to snap any other material,

  • making it potentially the strongest stuff in the universe.

  • This pasta layer might also influence how the crust above it breaks.

  • That means that, when astronomers get data from a neutron star's crust,

  • they might be able to extrapolate what's going on in the pasta below!

  • Of course, this is the only simulation of its kind that has been done so far,

  • so there should be more news to come as scientists perform similar tests.

  • In other news, earlier this month, scientists reported that they observed matter falling onto a black hole!

  • Now, that in itself isn't remarkable, that's how black holes work.

  • That's kind of their deal.

  • But these observations show matter moving at a really weird angle, and super fast.

  • And that's what makes this news!

  • Matter collects around black holes in massive accretion disks,

  • where the innermost matter can sometimes fall in.

  • All our models of black holes, and basically all our understanding of how they gobble up stuff,

  • assume that their accretion disks orbit with no tilt.

  • They're like big rings parallel to the hole's equator.

  • Except, there's no physical reason that needs to be true.

  • Accretion disks could have any orientation.

  • We had just never seen a black hole behaving like its disk wasn't parallel, until now.

  • In this new study, published in the Monthly Notices of the Royal Astronomical Society,

  • a team studied a black hole at the center of a galaxy almost a billion light-years away.

  • They used data from the European Space Agency's XMM-Newton telescope:

  • a space telescope that mainly observes things using X-rays, which black holes emit tons of.

  • Specifically, the group was looking for the fingerprints of certain elements.

  • These fingerprints appear as patterns of lines in an emission spectrum,

  • and each line is associated with an element emitting specific wavelengths of light.

  • If an element's pattern appears shifted from its usual wavelengths,

  • that likely means it's moving.

  • And scientists can use that difference to calculate the speed of the material.

  • In this case, the stuff falling into the black hole was moving around 30% the speed of light.

  • And if you think that's fast, you are totally correct.

  • It's significantly faster than what we usually see from this kind of matter.

  • What was maybe stranger, though, is that this stuff appeared to be falling directly onto the black hole,

  • not spiraling inward from a disk like we usually see.

  • Turns out, based on earlier simulations,

  • this is exactly what you would expect if the black hole had a tilted disk.

  • See, disk tilting can cause some instability,

  • and chunks of the accretion disk can break off and separate from the rest.

  • And those chunks can collide and cancel out some of each other's rotation.

  • And without all the spinning, the matter is pulled directly into the black hole way faster than normal.

  • Thanks to simulations, we'd thought that this so-called chaotic accretion might be pretty common for supermassive black holes,

  • but we'd never seen it happening.

  • After all, accretion events are pretty brief,

  • so we'd have to catch a black hole at just the right moment.

  • But now, it looks like we've finally done it!

  • Of course we'll have to do more studies to confirm these results,

  • but this is a big step forward in black hole research.

  • And it's always kind of nice when our simulations seem to be right.

  • Thanks for watching this episode of SciShow Space News, especially to our patrons on Patreon!

  • You help our team get access to the latest papers as well as film and edit all this cool research,

  • and we couldn't do it without you.

  • If you'd like to help us keep making episodes like this one, you can go to patreon.com/scishow.

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核パスタは史上最強の素材になるかもしれない|サイゾーウーマンニュース (Nuclear Pasta May Be the Strongest Material Ever | SciShow News)

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    林宜悉 に公開 2021 年 01 月 14 日
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