Placeholder Image

字幕列表 影片播放

  • [♪ INTRO]

  • Dark matter, dark energy, there are all kinds of things in space

  • that we have yet to figure out.

  • But your real hipster astronomers don't worry about famous mysteries like that.

  • They worry about stuff like the missing baryon problem: the fact that around a third of the

  • regular, ordinary matter in the universe has refused to show up on any telescopes.

  • At least, until now.

  • In last week's issue of the journal Nature, an international team of astronomers reported

  • that they've finally found evidence of the missing matter.

  • Honestly, it was right where everyone expected it.

  • But it took decades of new techniques, new telescopes,

  • and new knowledge to finally find it.

  • We have lots of ways of figuring out how much stuff is in the universe.

  • For example, we can look at the Cosmic Microwave Background, the echo of the Big Bang whose

  • colorful pattern depends on the universe's early makeup.

  • Or we can see how quickly the universe expands, which depends partially on the gravitational

  • pull of all of its matter on all of the other matter.

  • We can also look at how quickly early structures formed.

  • The list goes on from there, but one of the greatest achievements of modern astronomy

  • is that all our independent measurements using different techniques

  • tell pretty much the same story.

  • Most of the universe is dark energy, a poorly-understood, nonstop pressure spreading apart space.

  • Then, most of the rest is dark matter, a kind of something that exerts a lot of gravity

  • but doesn't emit or absorb any light.

  • Finally, a measly 5% of the universe is ordinary matter, or baryonic matter, it's the kind

  • that we and the Earth and the stars are made of.

  • Everything we've ever seen or touched, all the countless stars and planets, all of that

  • is just 5% of what's out there, with the rest being stuff

  • that we fundamentally don't understand.

  • Except, there's also a problem:

  • We can't actually find a big chunk of that ordinary matter.

  • When we count up the matter in all the stars, galaxies, and gas clouds we can see and then

  • extrapolate, we find that ordinary matter makes up only about 3% or so of the universe.

  • That means around a third of it is missing from our observations: We know it's there

  • from all those other measurements, but we haven't seen it with our telescopes.

  • And this is just normal matter!

  • This is the stuff that should be relatively easy to find!

  • Astronomers have dubbed thisthe missing baryon problem”, where baryonic matter is

  • stuff made of protons, neutrons, and electrons.

  • Most physicists have a slightly different definition of baryon,

  • but this is the one many astronomers use.

  • So far, researchers have mostly assumed that the missing baryons are hidden in certain

  • immense filaments of gas that sit between galaxies,

  • generally known as the Intergalactic Medium, or IGM.

  • The IGM can be millions of degrees Celsius, but the gas in it is so sparse that it would

  • feel cold if you were in the middle of it.

  • Astronomers think that a huge fraction of the universe's mass is tied up in these

  • filaments, but the IGM is hard to investigate directly.

  • See, it's mostly ionized hydrogen, or hydrogen that has lost its one and only electron.

  • But atoms give off and absorb light when the arrangement of their electrons changes.

  • So if the hydrogen in the IGM has no electrons, it won't absorb or emit any light.

  • Which makes it really difficult to study.

  • Thankfully, research over the last few decades has also indicated that there should be a

  • tiny amount of ionized oxygen in the gas, too.

  • Oxygen starts out with more electrons than hydrogen, so when it loses some and becomes

  • ionized, it still has others left over.

  • So we can try to see it.

  • And from there, we can extrapolate how much other stuff is in those filaments of the IGM.

  • To find evidence of that miniscule amount of oxygen, the astronomers in this new paper

  • used the European Space Agency's XMM-Newton, an orbiting X-ray telescope that can see the

  • kind of light that interacts with ionized oxygen.

  • But there's so little oxygen in the IGM that it doesn't just shine like a star;

  • you need a huge flashlight lighting it up.

  • For this team, that flashlight was a distant type of quasar sitting conveniently

  • far behind the gas.

  • These are objects powered by black holes that emit tons of radiation, more than many galaxies.

  • They looked at the quasar for about 18 days total over the course of two years, and all

  • their observations told them that some of the its light was getting absorbed by the

  • IGM's oxygen on its way to Earth.

  • Based on how much light was absorbed, and how much oxygen we think is in the IGM compared

  • with other elements, the team concluded that there's exactly enough matter in the IGM

  • to account for the missing baryons.

  • Even with two years of observations, though, this isn't the end of the mystery.

  • The team admits that there's still a lot of uncertainty, and that we need to look at

  • more filaments of IGM before the problem will truly be solved,

  • just in case this gas is an anomaly.

  • But this paper does show that there's a light at the end of the tunnel and that our

  • hypotheses are on the right track.

  • And once the missing baryon problem is solved, we'll just need to figure out

  • the other 95% of the universe, and we'll be all set!

  • Thanks for watching this episode of SciShow Space!

  • If you would like to keep learning more about the universe and how weird and cool it is,

  • and stay up-to-date with astronomers' newest findings, we've got you covered.

  • You can go to youtube.com/scishowspace for more videos and to subscribe.

  • [♪ 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

我們可能剛剛找到了宇宙中缺失的重子物質。 (We May Have Just Found the Universe's Missing Baryonic Matter)

  • 6 0
    林宜悉 發佈於 2021 年 01 月 14 日
影片單字