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  • [ intro ]

  • One of the things we assume to be fundamental about the universe

  • is that it's the same in all directions.

  • That means that over large scales,

  • matter is spread out pretty evenly,

  • things look more or less the same in every direction,

  • and you'll never find a corner of space with its own laws of physics.

  • And considering the universe is such an impossibly huge thing to explore,

  • it's comforting to think that somehow, fundamentally, it's pretty simple.

  • It all sticks to the same rules.

  • S

  • o you don't have to explore the whole thing to understand it.

  • This notion is called the cosmological principle.

  • But there's no law, exactly, that says the universe has to be that way.

  • So, what if it weren't uniform?

  • The main problem is that it would mean

  • there's only so much we can learn about the universe

  • by looking at it from our little perch in the Milky Way.

  • For example, fundamental laws like general relativity

  • which deals with gravity

  • assume that the universe is homogeneous.

  • If it's not, it would mean we might not understand gravitational interactions

  • in other parts of space as well as we think we do.

  • And our models of cosmology,

  • which describe how the universe began and evolved,

  • might not be as accurate as we think, either,

  • if the forces that push and pull aren't the same in every direction.

  • In short,

  • we tend to assume that studying small chunks of the universe

  • tells us about what it's like as a whole, and if that weren't true,

  • it would limit what we can ever know.

  • Thankfully, there are a lot of reasons to believe that it is uniform.

  • One of the strongest pieces of evidence comes from the cosmic microwave background,

  • a faint glow of radiation from the Big Bang that fills all of space.

  • Back in those first moments,

  • the universe consisted of just free electrons and nuclei in an extremely hot plasma,

  • along with a bunch of light particles, or photons.

  • In denser areas, photons had to work against the pull of gravity

  • as they radiated outward,

  • and that cost them some energy.

  • So the energy of the radiation was directly tied to how densely packed particles

  • were in the region it came from.

  • And we can actually still see that radiation today

  • that's the cosmic microwave background.

  • Which means it's one of the most direct ways we have of looking at the conditions

  • just after the birth of the universe.

  • Of course, that was 13.8 billion years ago,

  • but other studies have found that the cosmological principle seems to have held up as the universe

  • evolved.

  • For example, the Sloan Digital Sky Survey created an enormous,

  • three-dimensional map of the universe in greater detail than we'd ever seen,

  • and it showed that, no matter which way you look,

  • the distribution of galaxies is extremely similar on large scales.

  • So together, these two lines of evidence make a pretty strong case

  • for the cosmological principle!

  • But even though the universe seems to be homogeneous,

  • and cosmological principle seems to hold, the case isn't totally closed

  • because there's still no proof that it has to be that way.

  • And, of course, scientists are always testing their assumptions.

  • In the last decade, studies have actually raised some doubts about the cosmological

  • principle.

  • For example, in 2011, researchers published a study based on supernovas,

  • bright explosions of stars that let us see deep into the universe.

  • By measuring the distances to supernovas

  • and how fast they seem to be moving away from us,

  • astronomers can estimate how fast the universe is expanding.

  • Incredibly, this study found that, in some directions, supernovas appeared to be receding

  • faster than in other directions,

  • implying that the universe was expanding unevenly.

  • In other words, it suggested that the universe is not the same in every direction

  • exactly the opposite of what the cosmological principle says.

  • Then, in 2014, another team of researchers made another unusual discovery.

  • They were studying quasars,

  • the compact areas surrounding supermassive black holes at the centers of galaxies.

  • Quasars are extremely bright, and like supernovas,

  • they let us see into the distant universe.

  • By studying them, scientists found that,

  • across billions of light-years,

  • many different quasars seemed to be rotating around axes that lined up with each other.

  • Which is bizarre.

  • Because if there's nothing special about one direction or another,

  • you'd expect that quasars that have nothing to do with each other would just rotate around

  • random axes.

  • The implication that the universe had a preferred axis

  • went directly against the cosmological principle.

  • Which was potentially a really big deal.

  • Like the supernova study, it implied that the universe was anisotropic,

  • meaning it has different properties in different directions.

  • But as the saying goes, extraordinary claims require extraordinary evidence,

  • and the cosmological principle hasn't gone down the drain yet.

  • In a 2016 study, researchers considered how a preferred axis would have shaped the early

  • universe

  • and looked for telltale signs like spirals or gravitational waves in the cosmic microwave

  • background.

  • And they didn't find anything.

  • What's more, all of the anisotropies different studies have found

  • seem to be related in direction.

  • So the authors suggested that they have to do with the way we observe the universe,

  • rather than a problem with the cosmological principle.

  • It's still not proven, though,

  • so astronomers are continuing to look for evidence

  • that either confirms or defies our expectations.

  • And even though the cosmological principle seems to have stood the test of time,

  • it's important to keep checking.

  • Because anytime we study the universe, we're going into it with some assumptions

  • and sometimes the concepts that seem the most intuitive and obvious

  • are the ones keeping us from unlocking even deeper truths.

  • Thanks for watching this episode of SciShow Space!

  • And a special thanks to our President of Space, SR Foxley.

  • SR is one of the awesome people who support SciShow through Patreon,

  • and it's thanks to patrons like him that we can keep making science education free

  • on the internet.

  • If you're interested in supporting what we do or learning more about our wonderful

  • patron community,

  • head on over to Patreon.com/SciShow.

  • [ outro ]

[ intro ]

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如果宇宙不是統一的呢? (What If the Universe Isn't Uniform?)

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    林宜悉 發佈於 2021 年 01 月 14 日
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