Placeholder Image

字幕表 動画を再生する

  • Hey, Vsauce.

  • Michael here. And my tea is quite hot, but it's not the hottest thing in the

  • universe.

  • So what is? I mean, we know that there is an absolute zero,

  • but is there an absolute hot? A point at which something is so hot

  • it can't get any hotter. Well to find out, let's begin

  • with the human body. Your internal temperature

  • is not constant. 37 degrees, 98.6.

  • Sure. But those are averages. Your body's internal temperature fluctuates

  • by about one degree Fahrenheit -

  • half a degree Celsius - throughout the day in a cycle.

  • Assuming you sleep at night, at 4:30 in the morning

  • your body reaches its coolest natural healthy temperature.

  • And at 7 p.m. it reaches its highest.

  • But a dangerous fever is not good.

  • 108 degrees Fahrenheit is almost always

  • lethal. The highest recorded air temperature across

  • all of Earth has happened four times in Death

  • Valley, where it has reached 129

  • degrees Fahrenheit. 180 degrees Fahrenheit is the recommended

  • temperature for water

  • when brewing coffee. And at 210 degrees Fahrenheit,

  • a cake is done.

  • 2,000 degrees Fahrenheit is the temperature of lava

  • fresh outta the ground. But come on. Make your own lava

  • like Green Science Pro. This guy uses Fresnel lenses to focus the sun's

  • energy onto whatever he wants. This is a small piece of obsidian,

  • volcanic glass, which he can melt into actual lava

  • right in his backyard. Keep in mind that the Sun is having that effect

  • even though it is 93 million miles away from

  • Earth. Right up on the surface of the Sun is a different story.

  • The surface clocks in at 10,000 degrees Fahrenheit,

  • but the centre, where fusion occurs, is ridiculous.

  • Temperatures there reach 28

  • million degrees Fahrenheit, which is also known

  • as 15 million Kelvin. The Kelvin scale

  • has units that are the same size as a Celsius degree,

  • but it's an absolute scale, where 0 is

  • absolute zero. When matter reaches temperatures as high as those found in

  • the centre of the Sun,

  • an enormous amount of energy is radiated

  • away. If you were to heat only the head

  • of a pin to the temperature of the centre of the Sun,

  • it would kill any person within 1,000 miles of it.

  • Speaking of which, the energy emitted by an object

  • often tells us a lot about the temperature

  • of that object. Any object over absolute zero

  • emits some form of electromagnetic radiation.

  • You and me, we don't glow visibly, but we do emit

  • infrared light. We can't see it, but infrared cameras

  • can. WBT has great videos

  • and here he is, hiding inside an opaque black

  • trash bag. Now, we can't see him, but his body is

  • infra-redly glowing through it. If you want something to be the right

  • temperature to glow in the

  • visible spectrum, you'll have to reach the Draper point,

  • about 798 Kalvin. At this point almost any object

  • will begin to glow a dead red.

  • We can calculate the expected wavelength of radiation

  • coming off of an object because of its temperature and that wavelength

  • gets smaller and smaller the hotter and hotter the object gets.

  • It goes from radio waves to microwaves up through infrared divisible,

  • all the way to x-rays and gamma-rays, which are created in the middle

  • of our Sun. At temperatures as hot as the Sun,

  • matter exists in a fourth state. Not solid, not liquid, not gas,

  • but instead, a state where the electrons wander away from the nuclei

  • plasma. If you've watched my temperature lean back you know that you could make

  • plasma by microwaving fire

  • But don't do it. Besides, our Sun isn't even close to being the hottest thing in

  • the universe.

  • I mean, sure, 15 million Kelvin is pretty incredible,

  • but the peak temperature reached during a thermonuclear explosion

  • is 350 million

  • Kelvin, which hardly counts, because the temperature is achieved

  • so briefly. But inside the core of a star,

  • 8 times larger than our Sun,

  • on the last day of its life, as it collapses in on itself,

  • you would reach a temperature of 3

  • billion Kelvin. Or if you wanna be cool,

  • 3 GigaKelvin. But let's get hotter.

  • At 1 TeraKelvin, things get weird.

  • Remember that plasma we were talking about that the Sun is made of?

  • Well, at 1 TeraKelvin, the electrons aren't the only thing that wander away.

  • The hedrons themselves, the protons and neutrons in the nucleus

  • melt into quirks and gluons,

  • a sort of soup. But how hot

  • is a TeraKelvin? Frighteningly hot.

  • There's a star named WR

  • 104, about 8,000 light years away from us.

  • Its mass is the equivalent of 25

  • of our Suns, and when it dies,

  • when it collapses, its internal temperature will be so great

  • that the energy emitted, the gamma radiation it flings out into space

  • will be stronger than the entire amount of energy our Sun

  • will ever create in its entire lifetime.

  • Gamma ray bursts are quite narrow,

  • so Earth is most likely safe, but what if it wasn't?

  • Well, when WR 104 collapses,

  • even though Earth is 4,702 trillion miles away,

  • the energy it releases

  • would still be bad news. Exposure for 10 seconds

  • would mean losing a quarter of Earth's ozone layer,

  • resulting in mass extinction, food chain depletion

  • and starvation

  • from 8,000 light years away. Closer to home,

  • right here on earth in Switzerland, scientists have been able to smash

  • protons

  • into nuclei, resulting in temperatures much

  • larger than 1 TeraKelvin. They've been able to reach the

  • 2 to 13 ExaKelvin range.

  • But we are okay, because those temperatures last

  • for an incredibly brief moment and only involve a small number

  • of particles. Remember how we could calculate the wavelength of the

  • radiation emitted by an object based on its temperature?

  • Well, if an object were to reach a temperature

  • of 1.41 times 10 to the 32

  • Kelvin, the radiation it would admit would have a wavelength of 1.616

  • times 10 to the -26th nano meters,

  • which is tiny.

  • Like so tiny, it actually has a special name.

  • It is the Planck distance, which according to quantum mechanics

  • is the shortest distance possible in our universe.

  • Okay, well what if we added

  • even more energy? Wouldn't the wavelength get smaller? It's supposed to,

  • but yet it can't. This is where we've got a problem.

  • Above 1.41 times 10 to 32 Kelvin,

  • the Planck temperature, our theories don't work.

  • The object would become hotter than

  • temperature. It would be so hot

  • that what it is would not be considered a

  • temperature. Theoretically, there is no limit to the amount of energy we could

  • keep

  • adding into the system. We just don't know what would happen

  • if it got hotter than the Planck temperature. Classically,

  • you could argue that that much energy in one place would instantly cause a black

  • hole to form.

  • And a black hole formed from energy has a special name -

  • a Kugelblitz. So basically, what I'm trying to say

  • is when you want to tell someone you like that you think they are

  • hot, so hot that not even science can understand it,

  • just call them a Kugelblitz. Finally,

  • here is something fun. The Sun

  • is about 4.7 billion years old, about halfway through its life cycle

  • and so far it has burned 100

  • Earths worth

  • of fuel, which sounds like a lot, but the Sun

  • is the size of 300,000 Earths.

  • Because of that discrepancy, you can have a lot of mathematical fun comparing

  • your energy output to the Sun's. The Sun is way hotter than us

  • and it puts out way more energy than us. Bad Astronomy had a lot of fun with this one

  • and although it doesn't really mean anything, it is technically true,

  • because of the Sun's enormous size, that one

  • cubic centimeter of human puts out more

  • energy than an average cubic centimetre of

  • the Sun. Which should make you feel

  • quite warm inside.

  • И, как всегда, спасибо за смотрящий. [I, kak vsegda , spasibo za smotryashchiy.] [And as always, thanks for watching.]

Hey, Vsauce.

字幕と単語

ワンタップで英和辞典検索 単語をクリックすると、意味が表示されます

B1 中級

どのくらい熱くなれるのか? (How Hot Can It Get?)

  • 66 2
    龍 に公開 2021 年 01 月 14 日
動画の中の単語