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  • (clocks ticking)

  • (TV): Meteorologist Craig Beals here, and today is October 25th, 1985.

  • And it's shaping up to be a beautiful day in Hill Valley.

  • Sunny with highs in the 70s, so perfect day to go to the flee-market,

  • being held at the courthouse clock tower, the same clock tower that was struck

  • by lightning 30 years ago, at exactly 10:04 p.m.

  • And looking forward to tomorrow we see another beautiful day...

  • (amp buzzing)

  • (speaker squealing)

  • (explosion)

  • (Jake): I'm Jake, and how did I get here? Let's rewind.

  • Whew... I have two loves in my life: science and movies.

  • So, I decided to put myself in one of my favourite films, Back to the Future,

  • to find out if you could survive it.

  • Could you survive the massive amount of electricity from a lightning bolt,

  • time travel paradoxes, or being blown back by a giant amp pressure wave?

  • Could you survive Back to the Future?

  • (explosion)

  • (Back to the Future theme music)

  • - What we just saw is exactly what happens in Back to the Future

  • to Marty McFly. And then, he gets up and brushes himself off.

  • But what would actually happen to you in real life if you were faced with a sound wave?

  • In other words, a giant pressure wave that had so much force,

  • it could literally lift you off the ground and throw you across a room.

  • Well, to answer the question, we have an air mortar filled to 100 psi,

  • and a crash-test-dummy wired with sensors,

  • to measure head and neck trauma from impact.

  • The air mortar will recreate the effect of the giant amp pressure wave,

  • that Marty experiences, and the crash-test-dummy will let us know

  • what injuries Marty would actually sustain.

  • It wouldn't actually look like it does in the movie.

  • Instead, it would look like this...

  • Fire in the hole!

  • (explosion)

  • Let's watch that again in slow-motion.

  • In the movie, Marty is hit across his entire body with the pressure wave.

  • But the result would be the same if the pressure was targeted just to the chest.

  • Because the torso has so much more surface area and weight than the legs.

  • Either way, it results in exactly what we're seeing.

  • The legs flipping over the head as the upper body is driven into the ground.

  • Experiencing negative 600 Gs.

  • It's negative Gs because of the incredibly sudden deceleration.

  • As the head slams into the ground, the sensors in the dummy read an impact

  • of 4300 HIC. Head injury Criterion.

  • An HIC of 2000 is a 90% chance of life-threatening injury,

  • and our dummy experienced more than twice that.

  • Marty isn't going to be walking away from this.

  • Oh! One other fun fact: Using a slow-motion FLIR thermal camera,

  • we can see what would happen to your skin when it makes contact with the ground,

  • right here.

  • The ground and the dummy's head suddenly glow bright white

  • from the friction of scraping across each other.

  • So, to add insult to injury, Marty would have multiple layers of his skull scraped away,

  • before finally stopping.

  • So, clearly, this would be devastating.

  • And if for some miracle you were able to survive it,

  • you would still have to deal with...

  • ... the part of your body that is most sensitive to air pressure changes.

  • Your eardrums. But what would happen if your ear was subjected

  • to as much pressure as that amp can generate? Well...

  • That immense amount of pressure would instantaneously rupture your eardrum, like this...

  • Ew...

  • So, a massive pressure wave would do permanent damage to your ear,

  • and it's not just rupturing one eardrum, it's rupturing both of your eardrums,

  • which means that Marty McFly would've never heard the call from Doc,

  • assuming he'd even survive the massive pressure wave impact in the first place.

  • (car tires squealing)

  • - Jake! Look what I made!

  • - Doc! You made a... DeLorean.

  • - No, Jake, this is a time machine.

  • - It looks an awful lot like a DeLorean.

  • It does look pretty sophisticated in here.

  • How does it work?

  • - First, you turn on the time circuits.

  • This tells you where you're going, this tells you where you are,

  • and this tells you where you were. Punch in any date you want.

  • You wanna see when the Declaration of Independence was signed?

  • Just put in the date. Wanna go into the future,

  • and see when PewDiePie past 1 billion subscribers on YouTube?

  • - I don't know what any of those words mean.

  • - Oh, right... It hasn't happened yet.

  • Ah... November 5th, 1955.

  • - What happened on that date?

  • - I had just taken my last calculus final at MIT.

  • And I tripped on my pocket protector when it fell out of my pocket,

  • and I fell and hit my head, and I came up with the idea for the flux capacitor.

  • This is what makes time travel possible.

  • All you need is a little plutonium.

  • - Oh. Could I take it for a test drive?

  • Alright. Any important information I should know

  • before I take this around the block?

  • - Nope. Can't think of anything.

  • (car starting) - Alright. Back this up, here...

  • (engine roaring)

  • - Let's see how fast this thing can go.

  • (tires screeching)

  • Oh boy!

  • - Great Scott!

  • Don't go over 88 miles an hour!

  • (explosion)

  • - What happened?

  • Where are we?

  • (slow rock music)

  • Oh, no... It's 1955.

  • Okay. Uh, let's go back, huh? Let's just do that, nothing happened, it's okay.

  • Time circuit's on...

  • No! Argh! There's no more plutonium. Okay!

  • So... First rule of time travel is don't interact with anyone in a way that could potentially

  • influence or change the future.

  • So, we gotta go find Doc and figure out how we get back... to the future.

  • - Hey, man! That's a sharp looking set of threads you're sporting, brother!

  • And... what kind of car is this? - Oh, this old thing?

  • Well this is a 1981 DeLorean that my friend and kooky inventor, Doc,

  • turned into a time-machine, and then I accidentally drove it back to 1955,

  • and now I'm stuck here because the power source is plutonium,

  • and I don't have that.

  • - Hmm... Sounds like an interesting idea for a moving picture, man.

  • You know, I think I'm gonna call my cousin, Bob.

  • Bob Zemeckis, and tell him about this,

  • 'cause we can make a moving picture about the future, the car...

  • - Okay, that was my bad. You know what, let's just go over the basic principles,

  • the basic rules of time travel, and also maybe find someone who knows where Doc is.

  • (car horn honking)

  • (squeaking)

  • Hello. Does anyone know where Doc lives?

  • - Of course. 1640, Riverside Drive.

  • - Yes! Thank you. Thank you.

  • Okay, so... Back to the basics of time travel.

  • Let's imagine time as we normally think of it:

  • as a straight line.

  • But there are a few other ways to think about time, and travelling through it.

  • The first is that you have three timelines: past, present, and future.

  • If you were able to travel through time,

  • that means the past and future

  • exists concurrently with the present.

  • All of time is happening at the same time.

  • So when you travel from the present to the past,

  • you are leaving your timeline and going to another one.

  • The same if you were

  • to jump to the future.

  • The second theory involves a wormhole, or Einstein-Rosen bridge.

  • The basic idea being that a wormhole could act as a shortcut,

  • connecting two different points in space-time.

  • Even though wormholes have not been proven to exist,

  • this concept fits within Einstein's general theory of relativity,

  • whereas the other two do not.

  • And quick side note: In regards to relativity,

  • we can actually travel through time... kind of.

  • If an astronaut on the International Space Station had an atomic clock with them,

  • they'd notice that when coming back home,

  • their clock would've ticked off less time than those on Earth.

  • Because time is relative.

  • The elapsed time between events depends on the motion of the observer.

  • And you can actually experience this right now.

  • When you look into a mirror, the light needs to reflect off you,

  • onto the surface of the mirror, then off the mirror, into your eyes,

  • which your brain then needs to process into an image.

  • So when you do look in the mirror, what you are seeing looking back at you

  • is you from the very, very near past.

  • But back to our straight line. If we go from this point in time,

  • and jump to another point in time, we have created a loop.

  • We left in 1985 and traveled back in time to 1955.

  • That moment in 1985 has now become a fixed point,

  • meaning when I'm born in 1968,

  • I will continue forward until 1985,

  • when I will then go back in time.

  • And this will loop forever. There will always be a version of me who gets to 1985,

  • and travels back to 1955. It's a causal loop,

  • where every event causes another event,

  • that leads to the first event happening.

  • So, when we... If we get back to our present,

  • we will no longer be in a loop, but a version of us that is slightly in the past will be.

  • And then they'll get out, and another version will be, and so on, and so forth.

  • Now, is time travel as we normally think of it physically possible?

  • Well, not in real life,

  • because it is not compatible with the laws of physics,

  • as far as we know. But, we are in movie physics, so we need to find Doc

  • and get back to our own time.

  • (joyful music)

  • (knocking)

  • Doc! - Do I know you?

  • - It's me, Jake, from the future!

  • - I don't know anyone from the future,

  • and I definitely don't know anyone named Jake.

  • - Doc, you gotta believe me! Today's the day when after your calculus exam,

  • you slipped on your pocket protector and hit your head,

  • and that's how you thought of the flux capacitor!

  • - What are you doing? You're breaking the basic laws of time travel!

  • Although, in this case, the ripple in the timeline should be minimal.

  • Have you told anyone else about this? - No...

  • - Good! Because that would be a bootstrap paradox.

  • - The what, now? - The bootstrap paradox!

  • So, the bootstrap paradox

  • is when an object, or information, or a person

  • gets sent back in time, but that confuses the origin of the object.

  • For example, when Marty McFly goes back in time,

  • and he plays the song Johnny B. Goode by Chuck Berry,

  • and then Chuck Berry hears the song, and he's like,

  • "I like that song, I'm gonna make it mine." And he plays it on the radio.

  • If Marty had never gone back into the past,

  • would the song have ever been created? That's the bootstrap paradox.

  • - Cool! So, here's the deal. I accidentally travelled back to 1955 in your time machine,

  • and I don't have anything to power it to get back to 1985,

  • so do you have any idea about how to get 1.21 gigawatts to get me back home?

  • - Of course! 1.21 gigawatts, that would be enough power.

  • Although, the only thing powerful enough in 1955 to create that much power

  • would be a lightning bolt. - Great!

  • There's actually going to be a lightning strike at the clock tower at 10:04 p.m.

  • - What did I say about talking about the future?!

  • (thunder booming)

  • (eerie music)

  • - Huh. Everything we need is already set up.

  • - Whoa, whoa, hey... What are you doing?

  • - I was gonna ask you the same thing.

  • - Ah... I'm just working on some amateur weather experiment.

  • - Yes! That's right! Because you become a meteorologist.

  • He's the... - I like that. Meteorologist.

  • Craig Beals.

  • - Ugh... Why do I keep messing with the future?!

  • - Jake! We're running out of time!

  • (thunder booming, car starting)

  • - Alright, Doc, I think we're all set. Time circuits are... on!

  • Put my date in, and I guess I'll see you in a little bit.

  • - I'll see you in 30 years!

  • - You know...

  • Gotta say... This all worked out pretty great. (lightning striking)

  • - Great Scott! - Doc! What do we do?!

  • (Craig): Don't worry. I got this, guys.

  • - Oh, it's Craig.

  • - I'll just... grab the two ends and hold them together,

  • Like Doc Brown did in Back to the Future.

  • - Craig, I would not do that, that is an extremely bad idea.

  • - Why? Because I'm holding an uninsulated cable,

  • and I don't have insulated gloves? So the electricity's gonna flow through this wire

  • and into my body, and down into the ground,

  • because electricity's always looking for the path of least resistance

  • to get into the Earth, which means I'll likely be electrocuted,

  • and very little, if any, of the electricity will actually make it over to the car?

  • - Yeah, that's... actually exactly right. (thunder booming)

  • (electricity crackling)

  • - Uh... Do you think Craig's okay?

  • (Jake): I mean, that much electricity coursing through somebody's body

  • is definitely not good.

  • But to find out exactly how bad it would be, we happen to have a machine to test just that.

  • (thunder clap)

  • It takes an electrical current of 100 to 200 milliamps to be lethal.

  • That's just 0.1 to 0.2 amps.

  • And this six metre tall Tesla coil generates an electrical current

  • of 30,000, which happens to be the average amperage of a lightning strike.

  • And, yes, people have been struck by lightning before, and survived,

  • but that's generally because it's a branch of the lightning,

  • which travels either through the ground into them,

  • or strikes them from tens of metres above.

  • But what Doc brown experienced was a full-on lightning strike,

  • travelling down that cable, into his body.

  • But what would have happened to his body?

  • Well, to demonstrate, we have a discarded piece of pork to see what happens to your skin.

  • A ballistics dummy to see what happens to your insides.

  • And me. Except I'm not actually part of this demonstration,

  • because electricity is incredibly dangerous. I can't stress that enough.

  • Please do not play with electricity.

  • Which is why we're going to be standing over...

  • ...here. Over ten metres away. Let's do it.

  • (electricity crackling)

  • (eerie opera music)

  • (Jake): Let's watch that again.

  • Once the lightning reaches the wire touching our Doc Brown stand-in's hand,

  • that wire turns into the fourth state of matter: Plasma.

  • Because that bolt of lightning is extremely hot.

  • As much as five times hotter than the surface of the sun.

  • Meaning that your hands

  • holding that wire would be burned

  • to the point of not being recognizable.

  • And once the electricity comes into your body,

  • and goes through your arms, it enters your chest.

  • Your blood vessels would burst due to the heat and electrical discharge,

  • your heart would stop, and your internal organs would burn.

  • Also, if this dummy was wearing clothes, like Doc was in the movie,

  • the fabric would've immediately ignited, engulfing your body in flames.

  • Oh! And if the electrical current had entered your skull, it would cook your brain.

  • Cool.

  • So, since Doc Brown was holding onto the cables

  • as the electricity passed through, he would be horribly injured,

  • if not completely dead. Leaving Marty trapped in the past,

  • just like I am now.

  • However... Is there another bolt of lightning?

  • (thunder booming, lightning crackling)

  • - Jake, hurry!

  • You know, to time a lightning strike with the connection of a wire

  • would be nearly impossible, because the speed of electricity through a wire

  • is almost the speed of light.

  • Anyway... back to the action.

  • (electricity buzzing)

  • (engine revving)

  • (explosion, triumphant music)

  • It worked! We did it! See you in the future, Jake!

  • (Craig): Can I get some help, here?

  • (explosion)

  • (triumphant music)

  • (sighing)

  • - I'm back. Ten minutes before I previously left,

  • which should be enough time to hide the DeLorean,

  • so Doc and my other self don't see it, avoiding a potential paradox,

  • and enough time to stop my previous self from travelling back to 1955,

  • so a version of us isn't trapped in a causal loop forever.

  • Yeah...

  • So... I need to let myself know without causing another paradox.

  • I need to find something to write with.

  • Oh!

  • And as always, thanks for watching!

  • (eerie music, clocks ticking)

  • (TV): Meteorologist Craig Beals here, and today is October 25, 1985.

  • And it's shaping up to be a beautiful day in Hill Valley. Sunny with highs in the 70s,

  • the perfect day to go to the flee-market being held at the courthouse clock tower,

  • the same clock tower that was struck by lightning 30 years ago,

  • at exactly 10:04 p.m. (eerie music)

  • (explosion)

  • V Sauce! I'm Jake, still,

  • and I hope you enjoyed this Back to the Future-y episode of CYSTM,

  • or Could You Survive the Movies?

  • It was a lot of fun to make. And if you wanna see how we made it,

  • there is a behind the scenes video chronicling that.

  • And also, Craig and Diana made some awesome new science videos

  • that I cannot recommend highly enough that are in a playlist

  • with a bunch of other YouTube original learning videos.

  • It's really fantastic.

  • So, if you wanna watch the BTS, click right over here.

  • And if you wanna watch this learning playlist with Craig and Diana, click right here.

  • And as always, thanks for watching! (Back to the Future theme music)

(clocks ticking)

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BACK TO THE FUTUREで生き残れるか? (Could You Survive BACK TO THE FUTURE?)

  • 23 0
    Courtney Shih に公開 2021 年 01 月 14 日
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