The Universe s02e17 Episode Script
Gravity
ln the beginning, there was darkness and then, bang giving birth to an endless expanding existence of time, space, and matter.
Now, see further than we've ever imagined beyond the limits of our existence in a place we call "The Universe.
" lt is both mighty and meek.
Humanity's quest is to harness its power and escape its bonds.
Holy cow! This is what an astronaut feels.
lt creates and breaks the stars, the planets, the galaxies and directs their cosmic roller coaster ride.
Gravity is ourfriend and ourfoe.
Without it, life as we know it would end.
The Earth would literally explode.
lt is the magnificent and mystifying force that rules the universe: Gravity.
Gravity is the most pervasive force in the universe.
lt is at work on massive and minute scales on the routine and the extreme.
A surfer needs it to hang ten.
When you ride a wave, you're going to slide down the front and you're going to use that pull of gravity to get you going.
lt's your acceleration force.
lt's your accelerator.
Gravity is your accelerator.
A skier uses it to race downhill.
A snowboarder must have it to get big air.
lt acts on everything with mass, including us, 24/7 even when sleeping or standing.
Gravity here on Earth, of course, is always accelerating us down toward the center of the Earth at 32 feet per second squared.
At a theme park, gravity is the galactic gas that makes roller coasters roar and people scream.
The gravity of the Earth pulls us down and that's going to make us go really, really fast.
All objects with mass or energy-- particles, people, planets, stars, and galaxies-- produce gravity.
Omnipotent and omnipresent gravity attracts, governs, warps, shapes, makes and takes all matter and mass in the universe.
So it's pervasive.
lt acts on all things through extremely large distances and nothing escapes its pull.
lt is gravity that holds our solar system together.
The force of gravity is basically that thing that holds us on the planet keeps us from flying off.
lt is the cosmic glue that binds all matter in the universe together.
lfyou were to imagine taking two dice and putting them perfectly at rest out in the middle of space and separating them by a centimeter then what you'd see is that over a course of an hour or so those two dice would slowly come together and touch.
Gravity made ourworld.
Our Sun formed from a vast cloud of gas that gravitationally contracted.
Similarly, our Earth formed through the gravitational attraction of little particles, little bitty things gradually growing into a bigger and bigger object.
When it comes to gravity's pulling power mass and distance matter.
lt depends on the masses of each object the amount of matter within each object.
So it's proportional to the product of the two masses.
ln otherwords, the bigger it is the harder it pulls on other objects.
But that's not all.
And it's inversely proportional to the square of the distance between them.
This means ifyou double the distance between two objects the attraction or pull is only a quarter of its original strength.
The pulling power of gravity lets it direct the motion and movement of all matter, however massive, in the universe.
So you have whole galaxies, for example in orbit around each other.
Clusters of galaxies all orbit around their common center of mass.
But it is the practical potential of harnessing this relentless force that has obsessed scientists for centuries.
lt would literally fall to Galileo Galilei, the 17th-century truth-seeker to first recognize that gravity even existed.
Galileo found that objects having a different weight fall at the same rate.
So here's a very heavy steel ball and a light ping-pong ball of the same size.
And if l drop them at the same time they hit the ground at exactly the same time as well because they fall at the same rate.
To illustrate Galileo's most profound gravitational discovery that all objects, regardless of mass, fall at the same rate we take a ride on the mega-fast "Superman: The Escape" at Six Flags Magic Mountain in Southern California.
The theme park ride is the stage for a spectacular free-fall demonstration.
lt will showwhat happens when a carfull of people and a tennis ball fall from 415 feet in the air.
Okay.
Here we go.
All right.
Oh, my.
Oh, my God.
The riders are shot up the 41-story-tall tower at a hundred miles an hour.
With their eyes open, gravity will help them see a superhero.
Oh, my God.
Okay.
l'm going to drop this ball now and-- Oh, my God, it's floating around! lt's floating! lt's floating! Oh, the wind blew the ball away that time.
While we expect all objects to fall freely together, regardless of mass on a windy day, results aren't always perfect.
All right.
Oh, my God.
At the very top of the ride, when upward motion has stopped gravity takes over and the downward free fall begins.
l'm going to drop this ball and it's going to float.
lt's going to float.
Oh, it's floating.
lt's floating.
l'm going to release this ball now.
And then, for a few blissful seconds theme park thrill-seekers feel weightless as ifthey are free of gravity, or in what scientists call zero-G.
Oh, that one floated well.
That one floated well.
Oh, l'm going to try dropping the ball.
But zero-G isjust an illusion.
ln reality, gravity is running this ride.
lt's the force that yanks the car, the people, and the tennis ball indifferent to their mass, back down to Earth at the same rate.
Oh, that's a fantastic ride.
l mean, feeling oneself drop is amazing.
But what's really great is dropping the ball and seeing it floating above my face.
Now--l mean, it's falling.
l know it's falling but l'm falling at exactly the same rate.
lt doesn't matter how massive something is.
lt falls, under the force of gravity, at exactly the same rate.
Thanks to experiments like this we now know that objects all fall at the same rate.
But what would it take to launch a cannonball into orbit? When the famous British physicist Sir lsaac Newton saw the apple fall that, some say, hit him on the head it changed the world.
You got the apple falling from the tree and he looks up and sees the Moon in orbit around the Earth and judges that not only is the apple falling to Earth so too is the Moon.
But could the Moon really be falling? Load! By thinking of a cannon and the trajectory of the ball it shoots Newton used math to unlock a cosmic mystery.
lt came in his landmark publication, "Principia Mathematica," in 1687.
lsaac Newton has a famous drawing and in it, he draws a planet and a little mountain.
There's a little projectile first kicked off the mountain and it falls down a little bit.
You give it more speed, it goes a little farther out.
Now say you could just increase the force all you wanted.
lt can go fifty miles, it can go a hundred miles before it fell.
By adding more gunpowder and withjust the right angle offire a cannonball can be made to go faster and farther.
lnevitably, however, gravity wins pulling the cannonball back down to Earth.
The Earth is round and not flat, so Newton realized that if the cannonball is fired at sufficient speed the cannonball would actually go into orbit.
For that to happen, Newton determined the ball would need to be shot out of the cannon at17,500 miles an hour.
lt starts curving around the Earth and he realized that there must be a speed where it goes completely around the Earth and hits you in the back of the head never actually hitting Earth's surface.
And ifyou duck, it'll just keep going and lo and behold, you have an orbit.
But why doesn't the Moon fall to Earth? The Moon also has some sideways motion so for every little bit that it falls down it also moves off in this direction and the sum of all those motions is an orbit around the Earth.
Newton also realized that the Earth is in a giant freefall around the Sun.
With gravity forging the path, our planet rounds the Sun like an endless cosmic roller coaster ride.
Newton cracked the gravity code and physicists are still using his ideas to solve all sorts of problems some ofthem stranger than others like, what would happen if a person tried to travel through a tunnel from one side of the planet to the other? ln this wild scheme you would have to drive a straight-line tunnel right through the Earth and use gravity alone to propel a traveler down this so-called gravity express.
So, suppose you've got one ofthese tunnels and youjump in.
lnitially, the Earth is pulling down.
You're going toward the center of the Earth and so you're accelerating toward it.
But as you pass through the center ofthe Earth and start going out toward the opposite side the gravity ofthe Earth is trying to pull you back so it's decelerating you.
So gravity's actually having a braking effect.
There's no fear of shooting out the hole on the other side of the Earth at some tremendous velocity and shooting yourself back into space but, in fact, you reach the surface ofthe Earth exactly.
You would coast to a perfect rest.
ln forty-two minutes, you'd be there.
Whichever two cities you connect with a straight-line tunnel it takes gravity exactly forty-two minutes to get you there.
Thejourney from Los Angeles to Paris, forty-two minutes.
Suppose you wanted to go from Los Angeles to Tokyo forty-two minutes.
lt doesn't matterwhich path you take through the Earth.
Thejourney is always forty-two minutes long.
lt takes Newton's math to figure out why this works.
lfwe connect Los Angeles to NewYork digging a tunnel, obviously a tunnel would not go straight down but it has to go down at an angle.
The angle slows the speed of descent.
But the distance is also less.
And ifyou work out the equations lo and behold, the two effects cancel and you still get there in forty-two minutes.
lt takes forty-two minutes regardless of the path you take.
That's really cool.
Newton figured out what gravity does but it took the brilliance of physicistAlbert Einstein to work out why it was doing it.
Einstein realized that gravity is really caused by huge objects like stars and planets, literally bending space itself.
Like a massive rubber sheet space is curved where massive objects sit in it.
ln fact, Einstein proposed that the path planets take around their stars their orbits, are all a direct result of this curvature of space.
He said that what an orbit is is really something traveling in a straight line.
When something is free-falling towards another object it really isjust traveling in a straight line through space-time.
However, the curvature of space-time bends its path into a closed orbit but space itself curves it back in on itself.
This revolutionary discovery came when Einstein, in the early1910s realized that orbits of stars and planets in the observable cosmos behavejust as Newton's math predicted except one: Mercury.
lts orbit essentially wobbles.
Einstein described gravity as a curvature in space and time and the orbit of Mercury works perfectly when you take that into account.
Mercury isn't moving in flat space, but curved space around the Sun.
Then the orbit's perfect.
This curvature of space is at play in our own solar system.
Earth is simply following what it thinks is a straight-line path the shortest distance between two points in this intrinsically curved space.
Einstein not only determined that mass warps space it warps time, too.
So, henceforth, Einstein proclaimed physicists should not speak of space and time separately but of space-time as one unified object.
While it's uncomfortable to many the first time you hear it ifyou stop and think about it, it's actually quite obvious.
lf l'm going to make an appointment with somebody l don't say, "l'll meet you at 3:00.
" That's not enough information.
There's got to be a question that follows that.
What is that question? Where? lf l say, "Meet you in room 203.
" When? Any time you intersect with someone's else's life you do so at a time and at a place.
Einstein's realization that space is curved and that time and space are, in fact, intertwined is now the very definition of gravity.
Liftoff of the Space Shuttle "Discovery.
" Unlocking the secrets of gravity has enabled humanity to escape our earthly shackles and opened the universe for exploration.
But how can future astronauts on the long way to Mars survive the disabling effects caused by zero-G? Gravity is ourfriend and ourfoe.
lt is the fearsome force that propels a skier and the snowboarder down the mountain and shoots them into the air.
With enough momentum, an airborne snowboarder can feel forfleeting moments as if they are free of Earth's gravitational pull.
You're actually weightless when you go offthejump.
The period ofweightlessness is determined by the duration ofyour trajectory as a function ofyour velocity so that the snowboarder who gets really good big air may achieve a second, two seconds, even three seconds ofweightlessness.
But in the end, gravity wins and the high-flying, free-falling boarder just like the ball fired from the cannon is eventually yanked back down to Earth.
This free fall for the snowboarder as he or she goes over thejump and creates this trajectory isjust as much free fall as a cannonball going through the air and the trajectory is determined only by the velocity and the force of gravity.
Then, of course, what happens on the landing is another story.
But what if a snowboarder aspired to reach even greater heights? What if he wanted to overcome gravity and launch himself right off the planet? You want to leave Earth entirely and forever? Earth has what we call the escape velocity this magic speed where ifyou pass that speed you will escape Earth forever, never to return.
Escape velocity, the minimum speed any object needs to reach in order to escape from the Earth is about seven miles a second.
That's 25,000 miles an hour.
ln theory, even a snowboarder with enough momentum and aimed in the right direction can take offjust like a rocket.
Escaping Earth's gravity may not be realistic for a snowboarder but it has proven possible to launch people and projectiles into orbit.
You can leave systems.
Youjust need enough energy to do so.
And we've garnered enough energy and technological know-how to dojust that in ourvoyages to the Moon.
And our hope is that that will continue on to Mars and beyond.
To get to Mars and beyond mankind will have to harness gravity's energy just like we always do when we're seeking thrills to the extreme.
Gravity gives us two types of energy potential and kinetic.
Potential isjust that.
lt is energy that's being stored while kinetic is the result of all that pent-up potential energy.
This fantastic phenomenon works on a roller coaster.
As you're winched up on a hill, your potential energy is increasing.
You literally have more energy at the top of the roller coaster than at the bottom.
lt's notjust a weird, abstract thing.
You actually possess higher energy at the top and that's turned into speed, into kinetic energy as you go down that hill on the roller coaster.
Pretty soon, l'll be converting my potential energy to kinetic energy.
When a surfer hits that sweet spot on a wave they're using energy's double act.
NASA also uses this energy exchange principle to add some speed to their missions.
As a spacecraft nears the orbit of a planet it, too, gathers kinetic energy at the expense of potential energy.
Then as it rounds the planet on its cosmic coaster ride the craft gets a slingshot effect that punches it onward with more kinetic energy.
When the Voyager spacecraft visited Jupiter in 1979, 1980 it flew past Jupiter, and Jupiter tugged on it giving it extra motion, sort of a slingshot effect not only changing its direction of motion so that it was aimed towards Saturn but also speeding it up.
Knowing how to use the power of gravity will enable humanity to travel further and faster across the universe.
Having the physics formulated and the technology available isjust one part of the preparation for extraterrestrial travel.
Readying people for the rigors of space is the other.
Far away from Earth's gravitational pull in a spaceship on the long journey to Mars, for example future astronauts will have to learn to live, work, and play in an environment free of Earth's sizeable gravity one where they effectively feel weightless and all objects move equally and freely.
One fun way to experience the astronautical thrills and spills of space travel is to simulate it on a zero-G flight.
l'm really looking forward to this.
This is going to be an incredible experience.
By riding the ultimate roller coaster a specially modified zero-G Boeing 727 aircraft astrophysicist Alex Filippenko is about to go on the ride of his life.
This is going to be like a ball thrown up in the air weightless because it will be in free fall so l'll be floating around as though there's no ground holding me up.
The zero-G flight flies between This is about the same altitude as a regular commercial jet but that is where the similarity ends.
The water's the next one? The path it follows is a series of coaster-like rolling hills in the stratosphere.
Just like "Superman: The Ride" the super zero-G plane gathers potential energy as it climbs up at forty-five degrees.
Passengers feel this as an increase in weight.
Oh, yeah.
Gravity is measured in terms of g-forces.
One G is the amount of gravitywe feel standing on the surface ofthe Earth.
l'm going to get back down like this and get ready.
As the plane steeply climbs, accelerating upward the gravity G count rises and people feel heavier.
All right.
The plane is accelerating us upwards at about1.
8 G at its maximum.
As the flight approaches, then eases around the apex of the arc the plane, as well as all the people inside it are, in effect, in free fall.
Zero-G comin' up.
Oh, man, what an indescribable feeling.
Holy cow! Oh, l'm out in free space.
Floating, just floating.
This is what an astronaut feels.
The plane's trajectory induces weightlessness again and again by flying a series of these parabolic arcs.
Even though they are within the cabin of a plane the zero-G passengers are freely falling towards the Earth just like skydivers.
But what creates the sensation ofweightlessness? lt goes back to Galileo who showed that all objects fall at the same rate.
So, as the plane and the people inside fall freely toward Earth they maintain the same position relative to each other and that is why they feel weightless.
The feeling lasted twenty-five full seconds because, for twenty-five seconds, we were essentially in free fall.
lt was like Superman just flying through the air.
Oh, l cannot believe how it feels.
When thejet's engines reengage and end the free fall the passengers feel theirweight return.
As Einstein would say, weightlessness is but an illusion.
This is so awesome! So awesome! The zero-G plane takes advantage of something Einstein worked out back in 1916 in his general theory of relativity that acceleration is essentially the same as gravity.
When you are thrust upward in a rocket or the zero-G plane the G-forces you experience are the same as you would feel being tugged downward by the gravity of a massive object like a planet.
So gravity and acceleration create the same sensation.
That's how the passengers on a zero-G flight can feel like an astronaut and can experience thejoys ofweightlessness.
The ball and l arejust freely falling according to our natural path through curved space-time.
This is what Einstein's theory says.
lndependent ofthe mass, we all follow the same path.
Oh, yeah, this is unbelievable.
On the twenty-minute, fifteen-parabola flight there's time in between the frights and delights to further taunt the laws of gravity.
Look at that.
Look at that water.
Oh, look at that water.
l'm going to catch some.
Okay, here we go.
As well as entertaining weekend warriors the parabolic flights also inauspiciously called "The Vomit Comet" have a practical purpose.
They prepare NASA astronauts forworking and living in the zero-G environment of space.
With these sensational parabolic flights humans have learned how to simulate the absence of gravity.
But is it also possible to create artificial gravity in the lab? These experiments will lead to a successful exploration of Mars.
lt is in ourfuture.
At the dawn of the 21st century, overcoming the bonds of gravity and escaping Earth's sizeable tug have been realized.
The next step is to design and build the technology that will allow humans to travel, work, and live on exotic alien planets.
And we've garnered enough engineering know-how to dojust that in ourvoyages to the Moon.
Thanks to state-of-the-art technology humanity is on the brink of a new era in space exploration.
The trip to Mars is beginning here at our laboratory at MlT.
Artificial gravity may be one of the ways that we overcome the debilitating effects ofweightlessness.
Since the advent of the space age scientists have been concerned with minimizing the life-threatening risks and damaging effects of being weightless at zero-G.
The issues originally had to do with human survivability.
We didn't even know back in the Apollo period how people would react to stays in space of more than a few hours.
There was all kinds of concern about humans' ability to control a vehicle after being exposed to weightlessness for a long period of time.
A mission to Mars would require astronauts to be away from Earth's gravity for at least two, maybe three years.
The human frame is simply not designed for the absence of terrestrial one-G gravity.
The architecture of our bodies is designed to withstand ourweight under the forces of gravity.
Gravity determines how our cardiovascular system reacts so when you get out of bed and you go from being supine to upright there's a regulatory system that keeps the blood pressure reacting against the forces of gravity.
Experience has shown that being weightless for long periods leads to bone loss, muscle deterioration and life-threatening blood clots.
Aeronautical engineers at NASA and MlT are testing a personal centrifuge system that may mitigate the very real dangers.
They protect the heart, the bones, their muscles.
And even in these early experiments, we have every reason to believe that artificial gravity with short-radius centrifuges may be the universal antidote that we're looking for to protect people on the long trip to Mars.
Just like a theme park ride spinning a subject artificially creates g-forces.
To prevent motion sickness in the MlT ride astronauts are conditioned to keep their head still.
By spinning a person at thirty revolutions a minute the centrifuge imparts one G the same force felt pulling down a person standing on Earth.
Scientists hope that one day, a trip to Mars will be a reality.
Onboard, they believe there should be a personal centrifuge.
To get their Earthly gravity fill-up, could then just spend one hour a day on the machine.
We get onto it for a brief period every day and get spun up quite fast spun up in what l'll call a spin in the gym.
You go foryour exercise, you go foryourworkout you get your G tonic, your gravity tonic.
While a trip to Mars may still be decades away astrophysicist and seasoned skier Larry Young can dream of big air in the liberating gravity of Mars.
On the surface, there is three-eighths the tug of Earth's gravity.
Everyone likes to get some air.
Everybody likes a little bit.
Just think ifwe were on Mars.
A person who weighs would feel as if they weigh Although a Martian skier would fly down Olympus Mons at a third of the speed theywould on Earth the lower gravity also means that theywould get at least three times the big air.
ln the case of gravity, it's mass that matters.
The more mass you have, the stronger the pull of gravity.
So when you think about what yourweight would be on the Earth versus something more massive than the Earth, it's pretty direct.
lf something were twice as massive as the Earth you'd weigh about twice as much.
The Big Kahuna in our solar system is Jupiter.
On that planet, a 100-pound person would weigh a whopping 254 pounds.
Even if Jupiter had a solid surface a skier there would have to fight for big air.
What we already know about gravity, how it works and how it can be used for practical purposes could, in theory, even save the planet from its ultimate cataclysmic fate.
Here's how gravity can come to our rescue.
Gradually, in about five billion years our Sun will brilliantly flare, turn into a red giant gloriously burn up and die.
As this comes to pass, our inner solar system is engulfed and Earth's gravity and atmosphere will be radically altered.
At that point, life on the blue planet will end.
But astrophysicist Greg Laughlin has a plan to use gravity to save Earth.
This environment that we have here now would look very similar to the environment that is holding sway on Venus right now.
A crushing carbon dioxide atmosphere temperatures hot enough to melt lead.
But rest assured, if the worst hypothetical happens gravitational science could save mother Earth.
The one thing that we could do over the very long term is to somehow move the Earth's orbit out to a larger distance from the sun where the temperature isn't so hot.
And a way that you can do that, ifyou have enough time ifyou have billions ofyears available to you is to use a comet or an asteroid.
This mega move would require astronauts and engineers aboard a spacecraft to maneuver the comet or asteroid just in front ofthe Earth.
ln order to be most effective the comet has to fly very close to the Earth within orbital radius or so ofthe Earth.
Then on the cosmic roller coaster potential and kinetic energy are roused and gravity does the rest.
lf that happens, then the comet pulls the Earth forward the Earth pulls the comet backward and the net result is that the Earth is given a boost.
lt's given a boost to a slightly higher orbital radius slightly larger distance from the Sun.
And ifyou make one of these adjustments one of these passages every10,000 years or so then the Earth, over a period of a billion years can move at a fast enough pace outward to keep track with the steadily brightening sun.
lf however, the experts get the math wrong and the big gamble doesn't work, all bets are off.
And ifyou screw that up, then you can have a collision between the comet and the Earth.
So a hundred-kilometer object crashing into the Earth is absolutely an extraordinary disaster.
lt's the kind of thing that causes huge extinctions of gigantic numbers of species.
Of course, this is only an extreme hypothetical scenario but what is known for sure is that our continued existence today here on Earth is contingent on the presence of gravity.
lt allows for the perfect conditions for life and the pursuit of happiness.
One G produces the surfer's dream: A perfect wave.
But the wild waters enjoyed on Earth are not the only kind of gravity-generated waves.
There are cosmic waves so large they roll across the entire universe.
Tidal torrents of gravity-boosted particles roll across the cosmos.
According to Einstein these gravitational waves wash through the universe.
But what are they? Any change in the gravity sends a ripple through that fabric of space then moves at the speed of light.
That would be a gravity wave.
And why do they happen? lfyou have two objects, two compact stars each ofwhich curves space around them and they're orbiting one another then the result is, is that these two curved regions create a wave, a ripple in the structure in the shape of space that moves outwards carrying energy with it.
That's called a gravitational wave.
l mean, literally, you can think about space and time having a wave, just like an ocean wave in it that travels through the universe.
Gravitywaves arejust the same.
Any type of mass in motion, big or small generates a gravitational wave.
And like the Earth's ocean tides gravitational waves roll ceaselessly across the cosmos.
ln theory, a surfer launched into space could experience an out-of-this-world wipeout and warp.
lf a gravitational wave was created in space or somewhere and went through you, what would happen is you'd get fat and then you'd get skinny meaning that space was distorted.
Space in one direction made you fatter.
ln the other direction, it squashed you.
And it goes back and forth.
But for earthbound scientists to detect any faint G-wave signals the disturbance needs to be propagated by a massive cosmic object.
Black holes and spinning neutron stars can do it.
Another thing that can make a gravity wave is an explosion, say, a supernova.
A star explodes and it goes--whack-- and that actually pushes a gravity wave forward.
The tool to catch the light-like signal from a wave is the LlGO the Laser lnterferometer Gravitational Wave Observatory.
There are two identical, ground-based LlGO labs.
One is in Hanford, Washington and the other is more than 2,000 miles away near Baton Rouge, Louisiana.
lf a wave comes by, each lab's results will be vital to confirm the event.
Here's how it works.
Super polished glass mirrors are at the fulcrum of the interferometer which is a tool that basically compares two light wave measurements and identifies the differences between them.
Precision laser light is fired back and forth and split between two calibrated mirrors.
ln normal circumstances, as the light bounces up and down the 2 1/2-Mile long, L-shaped vacuum tubes the two laser beams are basically in sync.
This means the beams effectively cancel each other out and no light escapes the tunnel.
But when a gravity wave rolls through space is ever so slightly stretched or squashed.
As a result, the laser beams are thrown out of phase and only then a small amount of light is emitted a tiny signal, less than the diameter of a human hair of a proton will register.
Converted into a sound and a light signal it will be seen and heard.
The scientists' greatest hope is to catch the most massive event that ever occurred in the universe the Big Bang.
Gravitywaves may be our best chance to look very, very close to the beginning of the universe.
About 300,000 years after the Big Bang the universe was so dense, it was actually opaque to light.
Light could not travel through it.
So if light can't travel through the universe, what can? A gravity wave.
The problem is a miniscule signal from a gravitywave has yet to be caught.
lt's clearly hard.
ln fact, when Einstein predicted them, he thought it was a nice idea but no one would ever be able to detect them.
lt's only the advances of technology that give us a chance.
LlGO scientists, like astrosurfers live for the day when they can hang ten and ride theirvery own perfect wave of gravity.
We've seen what we think are the effects of gravity waves the loss of energy from a system by way of gravity waves but we never directly detected one.
That's one of the last frontiers.
lf the LlGO scientists' quest is successful and they catch a wave, it could change science.
So, l think that long term, it's first to understand gravity and then, even more interestingly, to understand the universe.
The force of gravity has domain over our universe.
lt created and can destroy the cosmos, the stars the planets, and the people.
lt controls our lives, our play, and our endeavors.
And therein is this cosmic ballet.
Our collective future depends on the grace and greatness ofthe mighty ruler of the cosmos, gravity.
Now, see further than we've ever imagined beyond the limits of our existence in a place we call "The Universe.
" lt is both mighty and meek.
Humanity's quest is to harness its power and escape its bonds.
Holy cow! This is what an astronaut feels.
lt creates and breaks the stars, the planets, the galaxies and directs their cosmic roller coaster ride.
Gravity is ourfriend and ourfoe.
Without it, life as we know it would end.
The Earth would literally explode.
lt is the magnificent and mystifying force that rules the universe: Gravity.
Gravity is the most pervasive force in the universe.
lt is at work on massive and minute scales on the routine and the extreme.
A surfer needs it to hang ten.
When you ride a wave, you're going to slide down the front and you're going to use that pull of gravity to get you going.
lt's your acceleration force.
lt's your accelerator.
Gravity is your accelerator.
A skier uses it to race downhill.
A snowboarder must have it to get big air.
lt acts on everything with mass, including us, 24/7 even when sleeping or standing.
Gravity here on Earth, of course, is always accelerating us down toward the center of the Earth at 32 feet per second squared.
At a theme park, gravity is the galactic gas that makes roller coasters roar and people scream.
The gravity of the Earth pulls us down and that's going to make us go really, really fast.
All objects with mass or energy-- particles, people, planets, stars, and galaxies-- produce gravity.
Omnipotent and omnipresent gravity attracts, governs, warps, shapes, makes and takes all matter and mass in the universe.
So it's pervasive.
lt acts on all things through extremely large distances and nothing escapes its pull.
lt is gravity that holds our solar system together.
The force of gravity is basically that thing that holds us on the planet keeps us from flying off.
lt is the cosmic glue that binds all matter in the universe together.
lfyou were to imagine taking two dice and putting them perfectly at rest out in the middle of space and separating them by a centimeter then what you'd see is that over a course of an hour or so those two dice would slowly come together and touch.
Gravity made ourworld.
Our Sun formed from a vast cloud of gas that gravitationally contracted.
Similarly, our Earth formed through the gravitational attraction of little particles, little bitty things gradually growing into a bigger and bigger object.
When it comes to gravity's pulling power mass and distance matter.
lt depends on the masses of each object the amount of matter within each object.
So it's proportional to the product of the two masses.
ln otherwords, the bigger it is the harder it pulls on other objects.
But that's not all.
And it's inversely proportional to the square of the distance between them.
This means ifyou double the distance between two objects the attraction or pull is only a quarter of its original strength.
The pulling power of gravity lets it direct the motion and movement of all matter, however massive, in the universe.
So you have whole galaxies, for example in orbit around each other.
Clusters of galaxies all orbit around their common center of mass.
But it is the practical potential of harnessing this relentless force that has obsessed scientists for centuries.
lt would literally fall to Galileo Galilei, the 17th-century truth-seeker to first recognize that gravity even existed.
Galileo found that objects having a different weight fall at the same rate.
So here's a very heavy steel ball and a light ping-pong ball of the same size.
And if l drop them at the same time they hit the ground at exactly the same time as well because they fall at the same rate.
To illustrate Galileo's most profound gravitational discovery that all objects, regardless of mass, fall at the same rate we take a ride on the mega-fast "Superman: The Escape" at Six Flags Magic Mountain in Southern California.
The theme park ride is the stage for a spectacular free-fall demonstration.
lt will showwhat happens when a carfull of people and a tennis ball fall from 415 feet in the air.
Okay.
Here we go.
All right.
Oh, my.
Oh, my God.
The riders are shot up the 41-story-tall tower at a hundred miles an hour.
With their eyes open, gravity will help them see a superhero.
Oh, my God.
Okay.
l'm going to drop this ball now and-- Oh, my God, it's floating around! lt's floating! lt's floating! Oh, the wind blew the ball away that time.
While we expect all objects to fall freely together, regardless of mass on a windy day, results aren't always perfect.
All right.
Oh, my God.
At the very top of the ride, when upward motion has stopped gravity takes over and the downward free fall begins.
l'm going to drop this ball and it's going to float.
lt's going to float.
Oh, it's floating.
lt's floating.
l'm going to release this ball now.
And then, for a few blissful seconds theme park thrill-seekers feel weightless as ifthey are free of gravity, or in what scientists call zero-G.
Oh, that one floated well.
That one floated well.
Oh, l'm going to try dropping the ball.
But zero-G isjust an illusion.
ln reality, gravity is running this ride.
lt's the force that yanks the car, the people, and the tennis ball indifferent to their mass, back down to Earth at the same rate.
Oh, that's a fantastic ride.
l mean, feeling oneself drop is amazing.
But what's really great is dropping the ball and seeing it floating above my face.
Now--l mean, it's falling.
l know it's falling but l'm falling at exactly the same rate.
lt doesn't matter how massive something is.
lt falls, under the force of gravity, at exactly the same rate.
Thanks to experiments like this we now know that objects all fall at the same rate.
But what would it take to launch a cannonball into orbit? When the famous British physicist Sir lsaac Newton saw the apple fall that, some say, hit him on the head it changed the world.
You got the apple falling from the tree and he looks up and sees the Moon in orbit around the Earth and judges that not only is the apple falling to Earth so too is the Moon.
But could the Moon really be falling? Load! By thinking of a cannon and the trajectory of the ball it shoots Newton used math to unlock a cosmic mystery.
lt came in his landmark publication, "Principia Mathematica," in 1687.
lsaac Newton has a famous drawing and in it, he draws a planet and a little mountain.
There's a little projectile first kicked off the mountain and it falls down a little bit.
You give it more speed, it goes a little farther out.
Now say you could just increase the force all you wanted.
lt can go fifty miles, it can go a hundred miles before it fell.
By adding more gunpowder and withjust the right angle offire a cannonball can be made to go faster and farther.
lnevitably, however, gravity wins pulling the cannonball back down to Earth.
The Earth is round and not flat, so Newton realized that if the cannonball is fired at sufficient speed the cannonball would actually go into orbit.
For that to happen, Newton determined the ball would need to be shot out of the cannon at17,500 miles an hour.
lt starts curving around the Earth and he realized that there must be a speed where it goes completely around the Earth and hits you in the back of the head never actually hitting Earth's surface.
And ifyou duck, it'll just keep going and lo and behold, you have an orbit.
But why doesn't the Moon fall to Earth? The Moon also has some sideways motion so for every little bit that it falls down it also moves off in this direction and the sum of all those motions is an orbit around the Earth.
Newton also realized that the Earth is in a giant freefall around the Sun.
With gravity forging the path, our planet rounds the Sun like an endless cosmic roller coaster ride.
Newton cracked the gravity code and physicists are still using his ideas to solve all sorts of problems some ofthem stranger than others like, what would happen if a person tried to travel through a tunnel from one side of the planet to the other? ln this wild scheme you would have to drive a straight-line tunnel right through the Earth and use gravity alone to propel a traveler down this so-called gravity express.
So, suppose you've got one ofthese tunnels and youjump in.
lnitially, the Earth is pulling down.
You're going toward the center of the Earth and so you're accelerating toward it.
But as you pass through the center ofthe Earth and start going out toward the opposite side the gravity ofthe Earth is trying to pull you back so it's decelerating you.
So gravity's actually having a braking effect.
There's no fear of shooting out the hole on the other side of the Earth at some tremendous velocity and shooting yourself back into space but, in fact, you reach the surface ofthe Earth exactly.
You would coast to a perfect rest.
ln forty-two minutes, you'd be there.
Whichever two cities you connect with a straight-line tunnel it takes gravity exactly forty-two minutes to get you there.
Thejourney from Los Angeles to Paris, forty-two minutes.
Suppose you wanted to go from Los Angeles to Tokyo forty-two minutes.
lt doesn't matterwhich path you take through the Earth.
Thejourney is always forty-two minutes long.
lt takes Newton's math to figure out why this works.
lfwe connect Los Angeles to NewYork digging a tunnel, obviously a tunnel would not go straight down but it has to go down at an angle.
The angle slows the speed of descent.
But the distance is also less.
And ifyou work out the equations lo and behold, the two effects cancel and you still get there in forty-two minutes.
lt takes forty-two minutes regardless of the path you take.
That's really cool.
Newton figured out what gravity does but it took the brilliance of physicistAlbert Einstein to work out why it was doing it.
Einstein realized that gravity is really caused by huge objects like stars and planets, literally bending space itself.
Like a massive rubber sheet space is curved where massive objects sit in it.
ln fact, Einstein proposed that the path planets take around their stars their orbits, are all a direct result of this curvature of space.
He said that what an orbit is is really something traveling in a straight line.
When something is free-falling towards another object it really isjust traveling in a straight line through space-time.
However, the curvature of space-time bends its path into a closed orbit but space itself curves it back in on itself.
This revolutionary discovery came when Einstein, in the early1910s realized that orbits of stars and planets in the observable cosmos behavejust as Newton's math predicted except one: Mercury.
lts orbit essentially wobbles.
Einstein described gravity as a curvature in space and time and the orbit of Mercury works perfectly when you take that into account.
Mercury isn't moving in flat space, but curved space around the Sun.
Then the orbit's perfect.
This curvature of space is at play in our own solar system.
Earth is simply following what it thinks is a straight-line path the shortest distance between two points in this intrinsically curved space.
Einstein not only determined that mass warps space it warps time, too.
So, henceforth, Einstein proclaimed physicists should not speak of space and time separately but of space-time as one unified object.
While it's uncomfortable to many the first time you hear it ifyou stop and think about it, it's actually quite obvious.
lf l'm going to make an appointment with somebody l don't say, "l'll meet you at 3:00.
" That's not enough information.
There's got to be a question that follows that.
What is that question? Where? lf l say, "Meet you in room 203.
" When? Any time you intersect with someone's else's life you do so at a time and at a place.
Einstein's realization that space is curved and that time and space are, in fact, intertwined is now the very definition of gravity.
Liftoff of the Space Shuttle "Discovery.
" Unlocking the secrets of gravity has enabled humanity to escape our earthly shackles and opened the universe for exploration.
But how can future astronauts on the long way to Mars survive the disabling effects caused by zero-G? Gravity is ourfriend and ourfoe.
lt is the fearsome force that propels a skier and the snowboarder down the mountain and shoots them into the air.
With enough momentum, an airborne snowboarder can feel forfleeting moments as if they are free of Earth's gravitational pull.
You're actually weightless when you go offthejump.
The period ofweightlessness is determined by the duration ofyour trajectory as a function ofyour velocity so that the snowboarder who gets really good big air may achieve a second, two seconds, even three seconds ofweightlessness.
But in the end, gravity wins and the high-flying, free-falling boarder just like the ball fired from the cannon is eventually yanked back down to Earth.
This free fall for the snowboarder as he or she goes over thejump and creates this trajectory isjust as much free fall as a cannonball going through the air and the trajectory is determined only by the velocity and the force of gravity.
Then, of course, what happens on the landing is another story.
But what if a snowboarder aspired to reach even greater heights? What if he wanted to overcome gravity and launch himself right off the planet? You want to leave Earth entirely and forever? Earth has what we call the escape velocity this magic speed where ifyou pass that speed you will escape Earth forever, never to return.
Escape velocity, the minimum speed any object needs to reach in order to escape from the Earth is about seven miles a second.
That's 25,000 miles an hour.
ln theory, even a snowboarder with enough momentum and aimed in the right direction can take offjust like a rocket.
Escaping Earth's gravity may not be realistic for a snowboarder but it has proven possible to launch people and projectiles into orbit.
You can leave systems.
Youjust need enough energy to do so.
And we've garnered enough energy and technological know-how to dojust that in ourvoyages to the Moon.
And our hope is that that will continue on to Mars and beyond.
To get to Mars and beyond mankind will have to harness gravity's energy just like we always do when we're seeking thrills to the extreme.
Gravity gives us two types of energy potential and kinetic.
Potential isjust that.
lt is energy that's being stored while kinetic is the result of all that pent-up potential energy.
This fantastic phenomenon works on a roller coaster.
As you're winched up on a hill, your potential energy is increasing.
You literally have more energy at the top of the roller coaster than at the bottom.
lt's notjust a weird, abstract thing.
You actually possess higher energy at the top and that's turned into speed, into kinetic energy as you go down that hill on the roller coaster.
Pretty soon, l'll be converting my potential energy to kinetic energy.
When a surfer hits that sweet spot on a wave they're using energy's double act.
NASA also uses this energy exchange principle to add some speed to their missions.
As a spacecraft nears the orbit of a planet it, too, gathers kinetic energy at the expense of potential energy.
Then as it rounds the planet on its cosmic coaster ride the craft gets a slingshot effect that punches it onward with more kinetic energy.
When the Voyager spacecraft visited Jupiter in 1979, 1980 it flew past Jupiter, and Jupiter tugged on it giving it extra motion, sort of a slingshot effect not only changing its direction of motion so that it was aimed towards Saturn but also speeding it up.
Knowing how to use the power of gravity will enable humanity to travel further and faster across the universe.
Having the physics formulated and the technology available isjust one part of the preparation for extraterrestrial travel.
Readying people for the rigors of space is the other.
Far away from Earth's gravitational pull in a spaceship on the long journey to Mars, for example future astronauts will have to learn to live, work, and play in an environment free of Earth's sizeable gravity one where they effectively feel weightless and all objects move equally and freely.
One fun way to experience the astronautical thrills and spills of space travel is to simulate it on a zero-G flight.
l'm really looking forward to this.
This is going to be an incredible experience.
By riding the ultimate roller coaster a specially modified zero-G Boeing 727 aircraft astrophysicist Alex Filippenko is about to go on the ride of his life.
This is going to be like a ball thrown up in the air weightless because it will be in free fall so l'll be floating around as though there's no ground holding me up.
The zero-G flight flies between This is about the same altitude as a regular commercial jet but that is where the similarity ends.
The water's the next one? The path it follows is a series of coaster-like rolling hills in the stratosphere.
Just like "Superman: The Ride" the super zero-G plane gathers potential energy as it climbs up at forty-five degrees.
Passengers feel this as an increase in weight.
Oh, yeah.
Gravity is measured in terms of g-forces.
One G is the amount of gravitywe feel standing on the surface ofthe Earth.
l'm going to get back down like this and get ready.
As the plane steeply climbs, accelerating upward the gravity G count rises and people feel heavier.
All right.
The plane is accelerating us upwards at about1.
8 G at its maximum.
As the flight approaches, then eases around the apex of the arc the plane, as well as all the people inside it are, in effect, in free fall.
Zero-G comin' up.
Oh, man, what an indescribable feeling.
Holy cow! Oh, l'm out in free space.
Floating, just floating.
This is what an astronaut feels.
The plane's trajectory induces weightlessness again and again by flying a series of these parabolic arcs.
Even though they are within the cabin of a plane the zero-G passengers are freely falling towards the Earth just like skydivers.
But what creates the sensation ofweightlessness? lt goes back to Galileo who showed that all objects fall at the same rate.
So, as the plane and the people inside fall freely toward Earth they maintain the same position relative to each other and that is why they feel weightless.
The feeling lasted twenty-five full seconds because, for twenty-five seconds, we were essentially in free fall.
lt was like Superman just flying through the air.
Oh, l cannot believe how it feels.
When thejet's engines reengage and end the free fall the passengers feel theirweight return.
As Einstein would say, weightlessness is but an illusion.
This is so awesome! So awesome! The zero-G plane takes advantage of something Einstein worked out back in 1916 in his general theory of relativity that acceleration is essentially the same as gravity.
When you are thrust upward in a rocket or the zero-G plane the G-forces you experience are the same as you would feel being tugged downward by the gravity of a massive object like a planet.
So gravity and acceleration create the same sensation.
That's how the passengers on a zero-G flight can feel like an astronaut and can experience thejoys ofweightlessness.
The ball and l arejust freely falling according to our natural path through curved space-time.
This is what Einstein's theory says.
lndependent ofthe mass, we all follow the same path.
Oh, yeah, this is unbelievable.
On the twenty-minute, fifteen-parabola flight there's time in between the frights and delights to further taunt the laws of gravity.
Look at that.
Look at that water.
Oh, look at that water.
l'm going to catch some.
Okay, here we go.
As well as entertaining weekend warriors the parabolic flights also inauspiciously called "The Vomit Comet" have a practical purpose.
They prepare NASA astronauts forworking and living in the zero-G environment of space.
With these sensational parabolic flights humans have learned how to simulate the absence of gravity.
But is it also possible to create artificial gravity in the lab? These experiments will lead to a successful exploration of Mars.
lt is in ourfuture.
At the dawn of the 21st century, overcoming the bonds of gravity and escaping Earth's sizeable tug have been realized.
The next step is to design and build the technology that will allow humans to travel, work, and live on exotic alien planets.
And we've garnered enough engineering know-how to dojust that in ourvoyages to the Moon.
Thanks to state-of-the-art technology humanity is on the brink of a new era in space exploration.
The trip to Mars is beginning here at our laboratory at MlT.
Artificial gravity may be one of the ways that we overcome the debilitating effects ofweightlessness.
Since the advent of the space age scientists have been concerned with minimizing the life-threatening risks and damaging effects of being weightless at zero-G.
The issues originally had to do with human survivability.
We didn't even know back in the Apollo period how people would react to stays in space of more than a few hours.
There was all kinds of concern about humans' ability to control a vehicle after being exposed to weightlessness for a long period of time.
A mission to Mars would require astronauts to be away from Earth's gravity for at least two, maybe three years.
The human frame is simply not designed for the absence of terrestrial one-G gravity.
The architecture of our bodies is designed to withstand ourweight under the forces of gravity.
Gravity determines how our cardiovascular system reacts so when you get out of bed and you go from being supine to upright there's a regulatory system that keeps the blood pressure reacting against the forces of gravity.
Experience has shown that being weightless for long periods leads to bone loss, muscle deterioration and life-threatening blood clots.
Aeronautical engineers at NASA and MlT are testing a personal centrifuge system that may mitigate the very real dangers.
They protect the heart, the bones, their muscles.
And even in these early experiments, we have every reason to believe that artificial gravity with short-radius centrifuges may be the universal antidote that we're looking for to protect people on the long trip to Mars.
Just like a theme park ride spinning a subject artificially creates g-forces.
To prevent motion sickness in the MlT ride astronauts are conditioned to keep their head still.
By spinning a person at thirty revolutions a minute the centrifuge imparts one G the same force felt pulling down a person standing on Earth.
Scientists hope that one day, a trip to Mars will be a reality.
Onboard, they believe there should be a personal centrifuge.
To get their Earthly gravity fill-up, could then just spend one hour a day on the machine.
We get onto it for a brief period every day and get spun up quite fast spun up in what l'll call a spin in the gym.
You go foryour exercise, you go foryourworkout you get your G tonic, your gravity tonic.
While a trip to Mars may still be decades away astrophysicist and seasoned skier Larry Young can dream of big air in the liberating gravity of Mars.
On the surface, there is three-eighths the tug of Earth's gravity.
Everyone likes to get some air.
Everybody likes a little bit.
Just think ifwe were on Mars.
A person who weighs would feel as if they weigh Although a Martian skier would fly down Olympus Mons at a third of the speed theywould on Earth the lower gravity also means that theywould get at least three times the big air.
ln the case of gravity, it's mass that matters.
The more mass you have, the stronger the pull of gravity.
So when you think about what yourweight would be on the Earth versus something more massive than the Earth, it's pretty direct.
lf something were twice as massive as the Earth you'd weigh about twice as much.
The Big Kahuna in our solar system is Jupiter.
On that planet, a 100-pound person would weigh a whopping 254 pounds.
Even if Jupiter had a solid surface a skier there would have to fight for big air.
What we already know about gravity, how it works and how it can be used for practical purposes could, in theory, even save the planet from its ultimate cataclysmic fate.
Here's how gravity can come to our rescue.
Gradually, in about five billion years our Sun will brilliantly flare, turn into a red giant gloriously burn up and die.
As this comes to pass, our inner solar system is engulfed and Earth's gravity and atmosphere will be radically altered.
At that point, life on the blue planet will end.
But astrophysicist Greg Laughlin has a plan to use gravity to save Earth.
This environment that we have here now would look very similar to the environment that is holding sway on Venus right now.
A crushing carbon dioxide atmosphere temperatures hot enough to melt lead.
But rest assured, if the worst hypothetical happens gravitational science could save mother Earth.
The one thing that we could do over the very long term is to somehow move the Earth's orbit out to a larger distance from the sun where the temperature isn't so hot.
And a way that you can do that, ifyou have enough time ifyou have billions ofyears available to you is to use a comet or an asteroid.
This mega move would require astronauts and engineers aboard a spacecraft to maneuver the comet or asteroid just in front ofthe Earth.
ln order to be most effective the comet has to fly very close to the Earth within orbital radius or so ofthe Earth.
Then on the cosmic roller coaster potential and kinetic energy are roused and gravity does the rest.
lf that happens, then the comet pulls the Earth forward the Earth pulls the comet backward and the net result is that the Earth is given a boost.
lt's given a boost to a slightly higher orbital radius slightly larger distance from the Sun.
And ifyou make one of these adjustments one of these passages every10,000 years or so then the Earth, over a period of a billion years can move at a fast enough pace outward to keep track with the steadily brightening sun.
lf however, the experts get the math wrong and the big gamble doesn't work, all bets are off.
And ifyou screw that up, then you can have a collision between the comet and the Earth.
So a hundred-kilometer object crashing into the Earth is absolutely an extraordinary disaster.
lt's the kind of thing that causes huge extinctions of gigantic numbers of species.
Of course, this is only an extreme hypothetical scenario but what is known for sure is that our continued existence today here on Earth is contingent on the presence of gravity.
lt allows for the perfect conditions for life and the pursuit of happiness.
One G produces the surfer's dream: A perfect wave.
But the wild waters enjoyed on Earth are not the only kind of gravity-generated waves.
There are cosmic waves so large they roll across the entire universe.
Tidal torrents of gravity-boosted particles roll across the cosmos.
According to Einstein these gravitational waves wash through the universe.
But what are they? Any change in the gravity sends a ripple through that fabric of space then moves at the speed of light.
That would be a gravity wave.
And why do they happen? lfyou have two objects, two compact stars each ofwhich curves space around them and they're orbiting one another then the result is, is that these two curved regions create a wave, a ripple in the structure in the shape of space that moves outwards carrying energy with it.
That's called a gravitational wave.
l mean, literally, you can think about space and time having a wave, just like an ocean wave in it that travels through the universe.
Gravitywaves arejust the same.
Any type of mass in motion, big or small generates a gravitational wave.
And like the Earth's ocean tides gravitational waves roll ceaselessly across the cosmos.
ln theory, a surfer launched into space could experience an out-of-this-world wipeout and warp.
lf a gravitational wave was created in space or somewhere and went through you, what would happen is you'd get fat and then you'd get skinny meaning that space was distorted.
Space in one direction made you fatter.
ln the other direction, it squashed you.
And it goes back and forth.
But for earthbound scientists to detect any faint G-wave signals the disturbance needs to be propagated by a massive cosmic object.
Black holes and spinning neutron stars can do it.
Another thing that can make a gravity wave is an explosion, say, a supernova.
A star explodes and it goes--whack-- and that actually pushes a gravity wave forward.
The tool to catch the light-like signal from a wave is the LlGO the Laser lnterferometer Gravitational Wave Observatory.
There are two identical, ground-based LlGO labs.
One is in Hanford, Washington and the other is more than 2,000 miles away near Baton Rouge, Louisiana.
lf a wave comes by, each lab's results will be vital to confirm the event.
Here's how it works.
Super polished glass mirrors are at the fulcrum of the interferometer which is a tool that basically compares two light wave measurements and identifies the differences between them.
Precision laser light is fired back and forth and split between two calibrated mirrors.
ln normal circumstances, as the light bounces up and down the 2 1/2-Mile long, L-shaped vacuum tubes the two laser beams are basically in sync.
This means the beams effectively cancel each other out and no light escapes the tunnel.
But when a gravity wave rolls through space is ever so slightly stretched or squashed.
As a result, the laser beams are thrown out of phase and only then a small amount of light is emitted a tiny signal, less than the diameter of a human hair of a proton will register.
Converted into a sound and a light signal it will be seen and heard.
The scientists' greatest hope is to catch the most massive event that ever occurred in the universe the Big Bang.
Gravitywaves may be our best chance to look very, very close to the beginning of the universe.
About 300,000 years after the Big Bang the universe was so dense, it was actually opaque to light.
Light could not travel through it.
So if light can't travel through the universe, what can? A gravity wave.
The problem is a miniscule signal from a gravitywave has yet to be caught.
lt's clearly hard.
ln fact, when Einstein predicted them, he thought it was a nice idea but no one would ever be able to detect them.
lt's only the advances of technology that give us a chance.
LlGO scientists, like astrosurfers live for the day when they can hang ten and ride theirvery own perfect wave of gravity.
We've seen what we think are the effects of gravity waves the loss of energy from a system by way of gravity waves but we never directly detected one.
That's one of the last frontiers.
lf the LlGO scientists' quest is successful and they catch a wave, it could change science.
So, l think that long term, it's first to understand gravity and then, even more interestingly, to understand the universe.
The force of gravity has domain over our universe.
lt created and can destroy the cosmos, the stars the planets, and the people.
lt controls our lives, our play, and our endeavors.
And therein is this cosmic ballet.
Our collective future depends on the grace and greatness ofthe mighty ruler of the cosmos, gravity.