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  • [MUSIC PLAYING]

  • When we look out at distant galaxies,

  • we see that they are all racing away from us.

  • We see that the universe is expanding.

  • The Big Bang Theory suggests that once the entire universe

  • was compacted into an infinitely small speck

  • at the beginning of time.

  • But was this really the case?

  • What parts of this theory are still under serious question?

  • [MUSIC PLAYING]

  • In the last episode, I showed you

  • why the Big Bang Theory is right, or at least,

  • what parts of it pretty much definitely happened.

  • Direct and convincing evidence tells us

  • that the universe was once much smaller, hotter, and denser

  • than it is now.

  • We're actually pretty sure we know

  • what happened all the way down to approximately 10

  • to the power of minus 32 of a single second

  • after the hypothetical beginning of time.

  • And at that point, the entire observable universe

  • was around the size of a grain of sand.

  • Now, we got down to that size by rewinding the laws of physics,

  • and in particular running the math

  • of Einstein's general theory of relativity backwards.

  • But how much further can we rewind

  • until we run into trouble?

  • Well, things get pretty weird before that 10

  • to the minus 32 seconds.

  • Now, remember, when the universe was younger than 400,000 years,

  • it was too hot for atoms to exist.

  • Well, before 10 to the minus 32 seconds,

  • it was too hot for the fundamental forces of nature

  • as we know them to exist.

  • In a previous episode, we talked about how the Higgs

  • field gives particles mass.

  • Well, at temperatures above 10 to the 15,

  • or a quadrillion Kelvin, it stops doing that.

  • It turns out that when you take this Higgs mass away

  • from the particles that carry the weak nuclear force,

  • they become just like the photon, which itself carries

  • the electromagnetic force.

  • This means that the weak and electromagnetic forces sort of

  • merge into the one electroweak force.

  • For a very brief period soon after the beginning of time,

  • these forces are combined.

  • It's called the electroweak era.

  • Sounds weird.

  • But perhaps weirder is that it's not really a mystery at all.

  • We pretty much know this happened

  • because we can actually make bits of the universe do this.

  • We can create energies needed to produce the electroweak states

  • in the Large Hadron Collider.

  • Yep, we can simulate the instant just after the Big Bang.

  • Our theories look really good to that point.

  • But once you get to a crazy 10 to the power of 29

  • Kelvin at an age of around 10 to the minus 38 seconds,

  • it's expected that this electroweak

  • force and the strong nuclear force-- that's

  • the force that holds atomic nuclei together--

  • also become unified into one force.

  • There are a lot of ideas of how this might happen.

  • And we call these grand unified theories,

  • except they aren't theories in the same sense as relativity

  • or evolution because we don't know which,

  • if any, are actually correct.

  • The problem here is that we can't test them yet.

  • We need to produce energies a trillion times larger

  • than is possible with the Large Hadron Collider.

  • Nothing we could build on the surface of the Earth

  • could do this.

  • Perhaps that's for the best.

  • So this is still a huge unknown.

  • We do think that we can describe gravity

  • and the shape of space time at these densities

  • and temperatures.

  • But we can't confidently describe this stuff

  • that the universe contained, the weird state of matter

  • that far back.

  • OK, rewind a bit further to 10 to the power

  • of minus 42 seconds of age.

  • And pack all of the galaxies in the entire observable universe

  • into a space 10 to the power of minus 20th

  • of the width of a proton.

  • That's the Planck length.

  • And here, physics kind of goes out the window.

  • See, at this point, general relativity

  • comes into serious conflict with quantum mechanics.

  • And we need a theory of quantum gravity,

  • a so-called theory of everything, to go further.

  • We can talk about why these theories don't play nice

  • together and what some of the resolutions

  • might be-- [CLEARS THROAT] string theory-- another time.

  • We're leaving it alone today because we don't actually

  • know whether the universe was really ever this small.

  • Remember, we've been rewinding the universe

  • using basic general relativity.

  • Is that valid?

  • Well, we don't yet have direct evidence

  • from those very early stages.

  • But there are some clues still visible at later times.

  • And those clues tell us we've missed something huge.

  • Let's undo our rewind a bit, fast forward again

  • to 400,000 years after that crazy first fraction

  • of a second.

  • The universe is space sized.

  • But it's still 1,000 times smaller

  • than the modern universe.

  • It's full of this hot glowing hydrogen plasma.

  • But at 400,000 years, it's cooled down just enough

  • to form the very first atoms, and in the process,

  • release the cosmic background radiation.

  • We now see this light as an almost perfectly smooth

  • microwave buzz across the entire sky.

  • That smoothness tells us that all

  • of the material in the universe when the CMB was released

  • was almost exactly the same temperature,

  • around 3,000 Kelvin, varying from one patch

  • to the next by at most one part in 100,000

  • across the entire observable universe.

  • Why is this so weird?

  • If you have a cup of coffee, and drop in some cold milk,

  • it will all smooth out and become the same temperature

  • after a bit of time.

  • Well, the universe works in the same way.

  • But based on the simplistic expansion

  • you predict from general relativity,

  • when the CMB was released, there just

  • hadn't been enough time for this mixing to have occurred.

  • See, in order for the most distant patch

  • of the universe we can see in that direction

  • to have the same temperature and density as the most

  • distant patch in that direction, there

  • needs to have been enough time for something

  • to travel between those points to diffuse and even

  • out that heat.

  • And there just wasn't, not even for light, the fastest thing

  • that there is.

  • Let's take this grain-of-sand-sized universe

  • at 10 to the minus 32 seconds.

  • A photon emitted on one side of that grain

  • wouldn't have time to get to the other side, not even

  • in 400,000 years.

  • See, although light is fast, those opposite edges

  • of the universe were traveling apart even faster.

  • Another way to say this is that those edges of the universe

  • have always been beyond each other's particle horizons.

  • A quick refresher.

  • Here's a nice review episode on cosmic horizons.

  • So those edges shouldn't be in each other's observable

  • universes, not then, not now.

  • This serious issue is called the horizon problem.

  • And it's a big deal that we need to sort out.

  • The only way around this problem is

  • to somehow have the universe, once upon a time,

  • be small enough so it could easily

  • get all nicely mixed together, and then pow, blow it up

  • in size much faster than general relativity would normally

  • allow.

  • The theory that describes this pow is called inflation.

  • The idea is the universe started subatomic, small enough

  • that it was able to even out its temperature and then

  • enter the state of insane, exponentially

  • accelerating expansion in which it

  • increased in size by a factor of at least 10 to the power of 26.

  • So 100 trillion trillion to something

  • like our grain of sand size at which point

  • it slowed down to its regular expansion rate.

  • But its edges are thrown way out of causal connection.

  • Yet, they look the same because they were once

  • causally connected.

  • This whole idea fixes our horizon problem.

  • In fact, inflation solves a number

  • of vexing problems with the Big Bang Theory so well,

  • in fact that most cosmologists accept that something like this

  • must have happened even though we don't have

  • any direct evidence for it.

  • There are a number of explanations for how

  • inflation might have happened.

  • And some of them actually call into question our understanding

  • of that very first instant of the Big Bang.

  • In this sense, it may be more accurate to think of the Big

  • Bang Theory not as a theory of the origin of the universe,

  • but instead as a theory describing

  • the period of expansion from a subatomic to a cosmic size.

  • Aspects of this theory have such hard evidence

  • that we know that the basic picture is right.

  • However, as with every really well-established theory,

  • there are boundaries to what the Big Bang Theory currently

  • explains.

  • Those boundaries are being chipped away at all the time.

  • Perhaps the theory will eventually

  • encompass a true origin for this universe.

  • Or perhaps that question will take us

  • far beyond the Big Bang.

  • One thing I stand by.

  • We can science anything, the origin of everything included.

  • We'll get back to that on future episodes of Space Time.

  • In the last episode, we laid out the evidence

  • for why the Big Bang definitely happened.

  • You guys let us know what you thought.

  • ElectroMechaCat asks why if the universe is expanding,

  • doesn't matter also get stretched with that expansion.

  • OK, this is a genuinely tricky question.

  • It's surprising the matter would not be stretched by expansion

  • because the bonds between and within atoms

  • are vastly stronger than any degree of expansion

  • on the scale of any material object in the universe.

  • That's if it were even valid to extrapolate

  • that expansion to the scale of objects or even to galaxies.

  • What we call the Hubble expansion of the universe

  • arises from the FriedmannLemaîtreRobertsonWalker

  • metric, which describes a space time in which all matter is

  • perfectly smoothly distributed.

  • That works on the largest scales in which galaxies and galaxy

  • clusters are a speckled foam on top of a much vaster space

  • time.

  • It doesn't work in galaxies or solar systems.

  • For example, the solar system is better described

  • with the Schwarzschild metric, dominated by the sun's

  • gravitational field.

  • In that metric, space is most certainly not expanding.

  • So you can have regions of non-expanding space embedded

  • in a globally expanding universe.

  • Kalakashi asks, does this mean if you

  • were to take every proton, neutron,

  • and electron in the universe, you

  • could fit them all into a space the size of a grain of sand?

  • This would be correct if you add the word "observable"

  • before the word "universe."

  • Everything that we can see to our cosmic horizon, so

  • the observable universe, was once

  • compacted into something smaller than a grain of sand,

  • and indeed, much, much smaller than that.

  • However, this isn't the same as saying

  • that everything that exists was compacted into that volume.

  • If our universe is infinite, then you

  • can compact it as much as you like

  • and it will still be infinite.

  • We don't know how large the greater universe is.

  • So we restrict ourselves to talking about the size

  • of the observable part of it.

  • James Beech writes, in the beginning

  • there was nothing, which exploded.

  • Now, a lot of non-scientists like to repeat this statement.

  • But no credible scientist has ever said this nor believes it.

  • So it's unfortunate that this statement is used

  • to deride the Big Bang Theory.

  • The Big Bang describes a series of events

  • that happened to the universe following

  • its existence in an extremely hot, dense state.

  • We have a ton of evidence that the universe was once

  • in such a state.

  • Perhaps our understanding of this state

  • will eventually lead to a theory of the origin of the universe.

  • But the Big Bang Theory as it stands

  • does not claim to explain such an origin.

  • [MUSIC PLAYING]

[MUSIC PLAYING]

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ビッグバン・セオリーの何が悪いのか?| 時空間|PBSデジタル・スタジオ (What’s Wrong With the Big Bang Theory? | Space Time | PBS Digital Studios)

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    怡蕙 に公開 2021 年 01 月 14 日
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