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  • This episode is sponsored by The Ridge.

  • Go to ridge.com/scishow and use promo codescishowto get 10% off your next order.

  • [♪ INTRO]

  • When you think of the universe, you probably think of all the bright stuff.

  • Stars and galaxies that light up the night sky.

  • And that's understandable.

  • I mean, in between those things, it looks like there's a lot of emptiness.

  • But more than half of all the matter in the universe is out there in the dark,

  • filling that empty space.

  • And I'm not talking about dark matter or anything like that.

  • I'm talking about the intergalactic medium.

  • It's the thinly-spread gas in the space between galaxies.

  • And even though it's basically invisible, it has a lot to tell us about the stuff we can see.

  • The intergalactic medium, or IGM, glows extremely faintly, so it's invisible to most telescopes.

  • In fact, it wasn't even discovered until the 1960s.

  • That's when scientists first discovered quasars,

  • incredibly bright objects in the old and distant universe.

  • Oddly, when they looked at these quasars, they found lots of wavelengths missing from their light.

  • Normally, light from stars is a continuum of all wavelengths.

  • And by splitting that light apart, kind of like you do with a prism,

  • you can see a continuous rainbow, or a spectrum.

  • But there are often gaps in that spectrum.

  • You get gaps when there's something sitting between the light source and your telescope,

  • absorbing specific wavelengths of light before they reach you.

  • That's what astronomers were seeing in the spectra from these quasars,

  • so they knew there had to be invisible matter sitting between us and these distant objects.

  • They could even tell what it was made of.

  • The patterns of absorbed lines told astronomers that this gas was mostly hydrogen

  • with some heavier elements thrown in, like carbon, silicon, and oxygen.

  • In general, the IGM is extremely thin, on average, it has less than one atom per cubic meter.

  • But around galaxies, gravity is able to hang onto a somewhat denser halo of gas,

  • which scientists call the circumgalactic medium.

  • And even though the gas in both of these regions is thin and invisible,

  • it's closely tied to the life cycle of galaxies, and has a lot to tell us about how they form and evolve.

  • These days, astronomers have some new tools for studying the IGM,

  • but a lot of the time, they still use the same old technique.

  • After all, studying the gaps in spectra can tell us about the temperature,

  • distance, age, chemistry, and motion of the gas in front of the light source.

  • Which is a lot to know about an invisible gas billions of light-years away!

  • The really cool thing is, since quasars are so old, by exploring their spectra,

  • we can actually explore gases from the early universe,

  • their light is carrying information that's billions of years old.

  • Astronomers are even able to look back to when the early universe gave birth to the first stars and galaxies,

  • just hundreds of millions of years after the Big Bang.

  • Back then, clouds of gas were made of pure hydrogen, and in them, astronomers can see clumps,

  • some slightly denser and hotter spots separated by thinner gas in-between.

  • And those hot clumps of hydrogen?

  • Those are the beginnings of the universe's first galaxies!

  • By using those clumpy spots as a starting point,

  • scientists have been able to simulate the evolution of the universe,

  • and better understand how we got the universe we live in today.

  • These days, the IGM still makes up 60% of matter in the universe.

  • But it's not the same old gas that was there all along.

  • Now it has a lot more heavy elements that were forged in stars,

  • because galaxies are constantly trading material with the IGM.

  • Gas likely gets blown out of active galaxies

  • by things like violent supernovas, black hole jets, and solar winds.

  • Violent events like galactic mergers can also toss a huge amount of dust out of a galaxy.

  • This seems to explain how the intergalactic medium got its sprinkle of heavy elements.

  • But galaxies aren't just blowing out gas; they're also pulling it in.

  • Once the circumgalactic gas moves away from the hot, turbulent environment of the galaxy,

  • it cools down.

  • As it slows, it becomes more susceptible to the galaxy's immense gravitational pull,

  • and some of it falls back into the galaxy.

  • This cycle of inflowing and outflowing gas is known as galactic recycling.

  • Models suggest that galaxies typically pull in about one solar mass of gas a year.

  • And this infalling gas is what keeps a galaxy alive!

  • That's how a galaxy can keep making new stars.

  • Recycling doesn't seem to be a perfect loop, though.

  • A 2019 study of our own galaxy revealed that more gas was flowing in than out.

  • So the Milky Way must be getting a boost of gas from somewhere.

  • Since our galaxy is one of the biggest in the neighborhood,

  • it may be leeching circumgalactic gas from smaller, neighboring galaxies.

  • Or it's possible that this gas is blowing in from deeper in the intergalactic medium.

  • Either way, we don't have all the answers yet,

  • but scientists hope that similar measurements from other galaxies

  • could tell us more about how galaxies interact with intergalactic gas.

  • Measurements like this could also help to answer the question of why galaxies die.

  • Because it's not exactly obvious.

  • As long as galaxies are recycling gas, it seems like they could keep making stars forever.

  • But they don't.

  • We see lots of galaxies whose stars are all red and old, with no youngsters in the mix.

  • But it's not clear why.

  • Observations of the area around dead galaxies

  • show that there is still gas that's cool enough to fall in.

  • But for some reason, it doesn't.

  • Scientists don't know what's stopping it, but whatever the answer is,

  • it's probably in the gas between galaxies.

  • Researchers hope that future surveys of dead galaxies

  • and their circumgalactic halos will offer more clues.

  • The space between the stars is still pretty murky territory, but as we get better at exploring it,

  • the intergalactic medium will have a lot to tell us about how galaxies live and die.

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  • [♪ OUTRO]

This episode is sponsored by The Ridge.

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銀河を生み出した目に見えないガス (The Invisible Gas That Gave Us Galaxies)

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    林宜悉 に公開 2021 年 01 月 14 日
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