It's great, it was created by Pendleton Ward, and in the show teenagers zip around the universe

visiting star systems and planets, and here is my question: When will we do the same?

Us humans, in real life.

I mean, we've managed to put people on the Moon, and land robots on asteroids, and Mars,

and even Titan, a moon of Saturn.

Interplanetary travel is scary cool. But, will we ever travel interstellarly? Certainly

it will happen, right? I mean, Voyager 1 is expected to reach interstellar space sometime

this year, or maybe in the next year or two. And it was launched way back in 1977. So,

shows like Bravest Warriors are pretty much just a glimpse of our future, maybe even one

within our lifetimes. Right? Well, we're going to need a DONG for this one. Something you

can Do Online Now Guys.

The Hayden Planetarium's digital universe allows you to explore a 3-dimensional map

of our Milky Way. Now, there are about 81 visible stars within just 20 lightyears of

our own Sun. The nearest is Proximus Centauri, which is only 4.3 lightyears away.

Getting there? Piece of cake. Piece of difficult cake, because a lightyear is an incredibly

long distance. It's the distance that light in a vacuum will travel in an entire year.

And, in just one second, light can travel so far as to circle the entire Equator of

Earth...7 times.

Now, a fast bullet can travel at about 1,500 m/s. And Voyager 1 is traveling at about 17,000

m/s, relative to the Sun. Also relative to the Sun, our Earth is orbiting at a speed

of 29,800 m/s- that's pretty fast. But, the fastest man-made object ever was the Helios

2 Solar Probe which traveled at a maximum speed of 70,220 m/s.

Impressive, right? Well, even at that speed, the fastest speed ever reached by any man

made object, crossing this little ol' gap and reaching Proximus Centauri would take

19,000 years.

But technology in the future is bound to be improved, along with the maximum speeds we

are able to obtain. Even using what we know now, a solar sail could easily provide the

acceleration needed to near-lightspeed speeds. And our current understanding of physics theoretically

allows for things like wormholes which, in theory, could move a spacecraft from one point

in space to another faster than light normally could.

And who could forget the famous Alcubierre drive? An idea that fits within most models

of our universe, and proposes a way to deliver a space craft to a distant object faster than

light can get there- not by moving the spacecraft, but, instead, by collapsing and expanding

space itself.

Things like wormholes and Alcubierre drives are theoretical, but, if they could, one day,

become a reality, how far away might that day be? It matters. And figuring out exactly

when in time we should begin an interstellar journey is called a Wait Calculation. Leave

too soon, and before a ship launched today, full of frozen embryos, ever got to its destination,

it would be passed by astronauts who left hundreds, or thousands, of years later, at

a point in time when technology was advanced enough to lap what we have today.

Andrew Kennedy calculated that, given the pace of our progress, as far as travel velocity

is concerned, and Earth's mean annual economic growth.

The soonest human civilization might ever reach Bernard Star, 6 lightyears away, is

1,104 years from today, which isn't within any of our lifetimes. It might also be a bit

optimistic because it assumes that we not only solve the problem of speed, but that

we also solve problems like "how to survive interstellar radiation for years?" or, "how

to avoid collisions with interstellar material at high speeds?"

It also assumes that before we achieve the technology needed to successfully interstellarly

travel, all of human kind isn't wiped out by some cataclysmic natural disaster. It may

sound unlikely, but we're not talking about the near-future, we're talking about thousands

of years from now. Let's put it this way- even given our current, slow means of space

travel, it's estimated that within 5-50 million years, we could theoretically explore and

colonize our whole galaxy.

That's a lot of time, though. In fact, statistically speaking, within the next 500,000 years, it's

very likely that Earth will encounter a meteorite nearly a kilometer across. Hopefully when

that happens we have the prevention abilities needed to keep ourselves safe. But, given

all this information, it's easy to see why the 2008 Joint Propulsion Conference concluded

that it was improbable that humans would ever explore beyond the solar system.

It's quite depressing to think that scenes like this one from Shutterstock may be destined

to only ever remain that- science fiction. Wait, how quickly is the camera moving in

that clip. We're used to seeing science fiction scenes like this, but a Nebula tends to be

lightyears across, which means that in this clip we're traveling at least the speed of

light, if not faster. Would it really look like that?

I covered this briefly in my black hole video, but not completely. If you were to travel

at the speed of light, or near the speed of light, the universe ahead of you wouldn't

look like it usually did. First of all, your field of view would increase- it would appear

as if the universe was receding away from you as you accelerated. At the same time,

all of the light reaching you would be blueshifted until you were left with this. You may have

seen this on Vsauce 2. It's the cosmic background radiation blueshifted all-the-way up into

the visible range.

MIT game lab offers a free, downloadable game that puts you in an environment where the

speed of light can be lowered all-the-way down to typical walking speed. You can experience

all of the visual effects I just discussed, but I wanted to know what it would look like

if the speed of light was where it is, and I took a journey from Earth to the Moon.

So, I enlisted my friend Liam from World of the Orange and New Music to put together a

simulation of what it might actually look like to accelerate to nearly the speed of

light and then slow down, during a trip from Earth to the Moon. Enjoy.

Whether or not you should believe that all the right factors will come together and humans

will one day travel that quickly or reach interstellar destinations largely comes down

to whether you want to be an optimist or a pessimist. But, what we've accomplished so

far is quite amazing considering how weak, flimsy, and vulnerable the human body is in

the vacuum of space.

Bad Astronomer and SciShow have great videos discussing this topic. And now, thanks to

the brilliant team at Bravest Warriors, I'm going to go to space. But not while wearing

a Vsauce suit, no, no, no, I'll do it naked. Whoa. Ok, not that naked. And also maybe some

muscles? Yep, so that's pretty much what I'll look like.

The moment I'm exposed to the vacuum of space my body would not inflate and explode. No,

the body is a very nicely contained system. But those parts of me that aren't well contained...they'll

be the first to go. The air in my lungs and digestive tract would quickly rush out. Moist,

soft tissues would rapidly lose water. My mouth, and lips, and eyes would dry out and

swell. As water was pulled to the surface of these things it would vaporize, and the

decrease in its pressure would cool my mouth and eyes to near-freezing. My body would inflate

to about twice its normal size as gasses in my blood came out of solution, slowly evaporating

away, cooling the surface of my skin. Oh, and the blood vessels in my eyes would likely

burst, spilling blood into my eyes which, along with all the other fluid in my eyes,

would be rapidly vaporizing on the surface, freezing and drying them out.

Within about 15 seconds I would go unconscious because oxygen wasn't reaching my brain. And,

as far as I'm concerned, that would be the end of the entire ordeal. For another 90 seconds

or so I would still, technically, be alive, but I wouldn't be aware of it or remember

any of it. My dead body would remain, internally, quite warm for a while because in the near

vacuum of space there isn't much matter to conduct of convect heat away from me. Instead,

I would really only lose heat through radiation, a much less efficient method. It would take

hours for me to cool down to the temperature of space, and by then, I would be nothing

but a dried-up piece of slightly bloated and stretched, dessicated human jerky.

If I was exposed to the Sun's full-on radiation, not filtered by the usual atmosphere of Earth,

I would be a grossly sunburnt piece of jerky.

In case that makes you hungry, let me give you some nutritional facts: 200 pounds of

human meat, in outer space, would eventually become about 120 pounds of freeze-dried jerky.

And given what would be left of me that would be edible as snack, I'd be worth about 115,000

calories.

Maybe humans are the only intelligent life in the universe, but if you believe that intelligent

life could have arisen on other planets, an interesting idea occurs: The Fermi Paradox.

Enrico Fermi calculated that given the number of planets believed to exist in our galaxy,

at least some of them must have been habitable to life as we know it. And, in many cases,

millions, and millions of years before life on Earth even existed.

So, if interstellar travel, traveling between stars and different solar systems, really

is possible for intelligent life to do, why have we not been visited by aliens yet? Well,

maybe we have been visited. Maybe they're here right now and we just can't perceive

them. Or, maybe we haven't been discovered. Or, maybe we are alone. Or, maybe we're just

not worth visiting...

So, what are you waiting for? Live your life in a way that makes traveling lightyears just

to hang out with you worth it. And, as always, thanks for watching.