Nova (1974) s43e09 Episode Script
Inside Einsteins Mind
It's a mysterious force that shapes our universe.
It feels familiar, but it's far stranger than anyone ever imagined.
And yet, one man's brilliant mind tamed it.
Gravity.
Using simple thought experiments, Albert Einstein made an astonishing discovery: time and space are shaped by matter.
You get rid of this force of gravity, and instead, we have curvature of spacetime.
Right now, the space around me is being squeezed and stretched.
He called it the "General Theory of Relativity.
" How did one person, working almost entirely alone, change everything we thought we knew about the universe? Einstein is toiling as the world seems to fall apart.
He was able with pure thought to solve the riddle of the universe.
"Inside Einstein's Mind," right now on NOVA.
Gravity.
The most familiar yet most mysterious of nature's forces.
100 years ago, Albert Einstein made a mind-blowing discovery: what we feel as gravity is in fact the push and pull of space and time itself.
He called his idea "general relativity.
" It is perhaps the most remarkable feat of thinking about nature to come from a single mind.
General relativity is undoubtedly one of the greatest scientific theories ever conceived.
It's a theory of space, time, and gravity.
One mathematical sentence, and from it, you can derive the understanding of the entire universe on the largest scales, and that is beautiful.
Only now, a century after it was first proposed, do we have the technology to explore the extremes of Einstein's great theory.
Supermassive black holes at the center of galaxies.
Waves of gravity that distort space and time.
The evolution of our entire universe.
How did a concept that explains so much come from the mind of one man? Einstein had a magical talent.
He could take a hard, physical problem and boil it down to a powerful visual image, a thought experiment.
Suddenly he realizes, "This is how the world works.
All this abstract nonsense is the correct theory of reality.
" To gain an insight into Einstein's mind and the true wonder of general relativity, we need to trace the crucial thought experiments that led to his great breakthrough.
The seeds for his ideas were planted when he was just a child.
Einstein grew up in a small house in Munich, in southern Germany.
His unique personality was evident early on.
Like many great innovators, Einstein was a rebel, a loner, but deeply curious.
He was slow in learning to speak as a child, so slow that his parents consulted a doctor, but he later said that that's maybe why he thought in visual thought experiments.
His sister remembers him building little card towers using playing cards.
He was a daydreamer, but he was deeply persistent.
Einstein's father, Hermann, manufactured electrical equipment.
He nurtured his son's interest in science.
On one occasion, he brought him a compass.
Now, you and I maybe remember getting a compass when we were kids, and we were like, "Oh look, the needle twitches and points north," but then we're on to something else, like, "Oh look, there's a dead squirrel.
" But for Einstein, after getting that compass, he developed a lifelong devotion to understanding how things can be forced to move even though nothing's touching them.
The young Einstein became gripped by a desire to understand the underlying laws of nature.
He developed a unique way of thinking about the physical world inspired by his favorite book.
The book Einstein loved told little stories, like what it'd be like to travel through space or go through an electrical wire.
And it made Einstein think visually.
These imagined situations that we often call "thought experiments" became a defining feature of Einstein's thinking.
One of the critical thought experiments that Einstein began to play with very young, around the age of 16, was trying to imagine what would happen if he could catch up with a light wave.
It's one thing to imagine a light wave zooming past him at some seemingly impossible speed, but what if he could somehow just propel himself really quickly? What would it look like if he could catch up with that light wave? What would he see? He said it caused him to walk around in such anxiety, his palms would sweat.
Now, you and I may remember what was causing our palms to sweat at age 16, and it was not a light beam.
But that's why he's Einstein.
This dream-like thought about the nature of light was Einstein's first step on the path to his great theory.
It stayed with him throughout his time at school and college.
He was extremely gifted in science and math as a young person and very bad at other classes, mostly because he kept cutting class and being very rude to his teachers.
Many teachers from his high school days on were convinced he'd never amount to anything.
He was a discipline problem, and he was bad news.
He applies to the second best university in Zurich, the Zurich Polytech, and gets rejected.
I'd love to meet the admissions director who rejected Albert Einstein.
But eventually he gets in, and he does moderately well, but not good enough to get a teaching fellowship.
And so he ends up at the Bern Swiss patent office as a third class examiner.
Undaunted by his university results, Einstein started work at the patent office in 1902, age 23.
Here, his job was to assess the originality of new devices.
He was immersed in the kinds of technical details that he'd been fascinated by as a very young kid.
And here he was, sitting in the kind of wave of the modern age.
This was the era of electrification.
So all the latest clever ideas for switching technology, for coordinating clocks in particular, those were all passing through his office.
Time zones had recently been introduced in central Europe, and accurately synchronizing clocks was a major challenge of the day.
Switzerland was a world leader in time technology.
Dozens of patents to link clocks passed through Einstein's office.
He could whip through these patent applications, and then out of his drawer, he'd pull his physics notes, and his boss was very indulgent and would sort of turn a blind eye as Einstein was doing his theories in his spare time.
It's really important to remember that theoretical physics was new when Einstein was a young man.
You could do quite a lot of this work by reading a relatively small number of science journals and making the calculations yourself.
Einstein's world in 1905 was dominated by two kinds of physics.
One was about 200 years old, founded by Isaac Newton, a British natural philosopher.
For Newton, all there is in the world is matter moving.
Newton showed that the motion of falling apples and orbiting planets are governed by the same force: gravity.
His equations are so effective, we still use them today to send probes to the farthest reaches of the solar system.
The other important theory of Einstein's day covered electricity and magnetism.
That branch of physics had been revolutionized in 1865 by the Scottish physicist James Clerk Maxwell.
Maxwell's theory describes light as an electromagnetic wave that travels at a fixed speed.
In Newton's world, the speed of light is not fixed.
Einstein could see that there's a contradiction between Newton and Maxwell.
They just don't fit together.
And one of the things Einstein hated hated Was contradiction.
If there's one kind of physics that says this and another kind of physics that says that and they're different, that's a sign that something's gone wrong and it needs fixing.
For months, Einstein wrestles with the problem.
Eventually, to resolve this contradiction, he focuses on a key element of speed: time.
He realized that any statement about time is simply a question about what is simultaneous.
For example, if you say the train arrives at 7:00, that simply means that it gets to the platform simultaneous with the clock going to 7:00.
In a brilliant thought experiment, he questions what "simultaneous" actually means and sees that the flow of time is different for an observer that is moving versus one that is standing still.
He imagines a man standing on a railway platform.
Two bolts of lightning strike on either side of him.
The man is standing exactly halfway between them and the light from each strike reaches his eyes at exactly same moment.
For him, the two strikes are simultaneous.
Then Einstein imagines a woman on a fast-moving train, Traveling at close to the speed of light, what would she see? As the light travels out from the strikes, the train is moving towards one and away from the other.
Light from the front strike reaches her eyes first.
For the woman on the train, time elapses between the two strikes.
For the man on the platform, there is no time between the strikes.
This simple thought has mind-blowing significance.
Simultaneity, and the flow of time itself, depends on how you're moving.
If there's no such thing as simultaneity, then there's no such thing as absolute time everywhere throughout the universe, and Isaac Newton was wrong.
This concept that time, and space as well, are relative became known as special relativity.
It led to remarkable results, such as the famous equation relating energy to mass.
Einstein published this article in 1905 to exactly no acclaim.
Most people ignored it.
This was not setting the world on fire.
Two years go by before a very eminent physicist, Johannes Stark, invites Einstein to write a review article on Einstein's own work, precisely because no one was paying attention.
And he begins thinking about ways to generalize and to push his own results from 1905.
What if he considers not only a train moving at a fixed speed past the platform? What if that train begins to speed up or slow down? What if there's acceleration? Adding acceleration to the equations was his first task.
Then there was that mysterious Newtonian force of gravity to contend with.
In Newton's theory, gravity is a force that acts instantaneously.
But special relativity says that's impossible Nothing can travel faster than light.
What Newton's theory tells you is that suppose the sun were to disappear, the orbit of the earth should change at that very moment.
But the notion of "at that very moment" in two different places is exactly one of these notions that special relativity has told you isn't a good physics notion.
So you've now got this challenge of trying to work out how to take the success of Newton's theory of gravity but fit it into this new special relativistic picture.
It was only when Einstein began to understand the link between gravity and acceleration that things began to fall into place.
We all know that when we are accelerated, and of course now we have cars and airplanes to give us the physical feeling, if you're in an airplane and it's taking off, you are pushed back in your chair, you feel actually kind of a force pushing you back, which feels very similar to the force of gravity.
But you need the brilliance of Einstein to explain why they are related.
Suddenly, he hits upon what he describes as the happiest thought of his life.
If gravity and acceleration feel the same, perhaps they are the same.
Again, he examines the idea in a beautiful thought experiment.
He imagines a man in a box floating weightlessly in a distant region of space in zero gravity.
Suddenly, the man stops floating and accelerates downward until he's standing in the box.
What has happened? Either the box is now close to a planet and the force of gravity has pulled the man to the floor, or someone has attached a rope and the box is now being pulled continuously and accelerated upwards.
So which is it? Gravity? Or acceleration? Without being able to see outside, the man can't tell what's causing his fall to the floor.
Einstein realized there is no way to tell the difference between sitting in a gravitational field and being accelerated.
These are equivalent situations The fact that these two effects are the same, give the same result, means that gravity is acceleration.
It's not just like acceleration; it's the same thing.
It's a big breakthrough.
Einstein's theory of special relativity worked for motion at a constant speed.
By extending his ideas to acceleration, he could begin to formulate a new theory of gravity.
In 1912, Einstein is living in Zurich with his wife Mileva and two young sons, Hans and Eduard.
The academic world had realized the importance of special relativity, and his career had taken off.
He's now a professor at the esteemed Swiss Federal Institute of Technology, but spends as much time as possible working on his theory.
He needs mathematics that describes how objects move in space and time and soon realizes that the best tool for the job is a strange but powerful concept called "spacetime.
" If I think of space, I know that I can find anything if I know where it is north-south, east-west, and up-down, three points.
But that doesn't mean I can find it, because I also have to know where it is in time.
And so if we start to think, to know everything about an event in the universe, I have to know not just its spatial coordinates, but also its time coordinate.
I can begin to think about where it is in spacetime.
Imagine a camera filming an action, capturing each moment in time as a single frame.
Einstein basically tells us, "Think of the movie reel.
" So you have all these little pictures.
Now, cut them apart one by one and stack them on top of each other, you get this pile.
And if you go up in the pile, you go up in time.
And now kind of glue them all together into one big block, and that block has both space and time, and that's the spacetime continuum.
It's almost looking at a movie not frame by frame, but seeing the whole movie at once.
They would now be kind of two strands going up in space and time, and they would be kind of spaghetti strands.
In fact, we all are spaghetti strands moving in this spacetime.
Einstein feels that spacetime is the natural arena in which his theory of relativity should play out.
But now he needs sophisticated mathematics.
By your standard or mine, Einstein was good at math.
He was Einstein.
But he was not really a mathematician per se.
He didn't prove theorems, he didn't pore over math books.
He was a physicist.
He did thought experiments.
He thought of very tangible, concrete situations and what would happen.
So when it came time for him to really bear down to the absolute cutting edge mathematics of his day, he required help.
At university, Einstein had skipped the geometry classes, letting his friend Marcel Grossman take notes for him.
Grossman had excelled in geometry and was now chairman of the math department.
He suggests Einstein uses advanced mathematics in which the shape of space and time could be curved.
Because spacetime has a geometry, he thinks to himself, "Well, maybe it's the actual shape of spacetime itself that is giving rise to gravity.
" After months of work, Einstein has an extraordinary idea.
"What if spacetime is shaped by matter, and that's what we feel as gravity?" In struggling to figure out what causes gravity then, Einstein has this great insight.
It is simply that a mass distorts the shape of spacetime around it.
So you get rid of this force of gravity, and instead we have curvature of spacetime.
In Einstein's universe then, if space were empty, it would be flat.
There'd be nothing going on.
But as soon as you put objects down, they warp the space and time around them, and that causes a deviation of the geometry so that now things start moving.
Everything wants to move as simple as possible through space and time.
But Einstein tells us that mass sculpts space and time, and it's the curved motion through this sculpture that's the force of gravity.
We have this feeling that the reason I can feel pressure on the soles of my feet, that the reason things are going to drop when I throw them, are because there's a force attracting us down to the center of the earth.
What general relativity tells you is that's not the right way to think about what's going on there.
What's really going on is that your natural path in spacetime would take you to the center of the earth, and what's actually happening is the floor is getting in the way, it's pushing you upwards.
When we look at it, we go, "Ah, the force of gravity" But Einstein says, "No, no, no, the curvature of spacetime.
" It's a stunning insight.
Just as an ant might feel forces pulling it left and right as it walks over crumpled paper when it's simply the shape of a surface dictating its path, Einstein saw that what we feel as the force of gravity is in fact the shape of the spacetime we're moving through.
Einstein now has everything he needs to formulate his final theory of gravity.
But he makes a critical mistake.
He misinterprets one of his equations, and unaware of his error, continues working on incorrect ideas.
The point at which Einstein is going to give the most essential equations of the theory, Einstein considers something like them and then says, "Ah, but these don't work," and then writes down the wrong equations.
What follows are alternations of confidence and despair as he convinces himself that everything was fine with this theory, and then he realizes that things aren't so good with the theory.
It is a long, dark period for Einstein as he struggles to reconcile himself with a theory that is just not working.
Two years later, Einstein is in Berlin.
At just 36 years old, he has one of the most prestigious positions in physics.
But he is still struggling with his theory.
By 1915, he'd reached the pinnacle of the profession.
He's in the Prussian Academy and a professor at the University of Berlin.
But his marriage is falling apart, his wife and his two kids have moved back to Switzerland, so he's pacing around almost all alone in this apartment in Berlin.
And now he has a competitor.
Einstein had enthusiastically shared his ideas with the brilliant mathematician David Hilbert.
Hilbert was so impressed, he decided to work on the theory himself.
Einstein is now in a race to the finish with one of the world's best mathematicians.
This is unfolding in a remarkably dramatic period in history.
World War I has begun to ravage central Europe.
Einstein is not just toiling in the abstract; he's toiling as the world seems to fall apart.
By November 1915, Einstein is scheduled to present his work in a series of four weekly lectures at the esteemed Prussian Academy.
But he's struggling to formulate his ideas.
In the midst of these challenges, letters arrive from his wife in Zurich pressing the issue of his financial obligations to his family and discussing contact with his sons.
As his lectures begin, his theory is still far from complete.
The pressure on Einstein is huge.
He would give a lecture, revise it, give it again.
Spot mistakes, correct them, get up on the podium, explain what was wrong in the previous week's lecture, correct it and then move on, and then do that again and again for four weeks running.
His work to convince them of the truth of this absolutely radical new theory of relativity that he was proposing is one of the most intense periods of work in the history of science.
Somehow, he's able to focus on his theory with an incredible intensity, and he makes his breakthrough.
He tests his equations on a problem that Newton's theory of gravity couldn't solve: the orbit of Mercury.
Mercury's path around the sun has an anomaly that Newton's theory can't explain: it deviates slightly each time it goes round.
Einstein calculates the orbit with his new equations.
The answer is correct, exactly what astronomers had observed.
He'd found the final equations for his general theory of relativity.
You have to think about the hubris of being Albert Einstein.
He had already thrown out Newtonian mechanics with special relativity, and then he had gone off on his little personal quest to incorporate gravity.
And at the end of the day, he boils it down to a prediction for a number that had been observed: the procession of the orbit of Mercury.
And, miraculously, when the pages of algebra work out to their end, you get the right answer.
And suddenly, it's not just playing with equations anymore; he realizes this is how the world works.
All this abstract nonsense is the correct theory of reality.
Einstein is at last able to present a successful theory.
That's a triumphant moment, one of the great moments in the history of physics, and, for Einstein, a victory very much against the odds, and he'd won.
On the 25th of November 1915, Einstein lays out his findings in his climactic fourth lecture at the Prussian Academy.
He presents general relativity.
The theory can be written as a single equation.
It condenses sprawling complexities into a beautifully compact set of symbols.
So the formula is really simple: G-mu-nu equals G for the shape of spacetime and T for the distribution of mass and energy.
So this very simple formula captures all of Einstein general relativity.
It's a beautiful, simple equation but it's a lot of work to unpack the symbols, the mathematical symbols, and see how in this very simple formula, the whole geometry of the universe is hidden.
It's kind of an acquired taste to see the beauty.
It's also a signature formula for Einstein.
The true mark of his genius is that he combines two elements that actually live in different universes.
The left hand side lives in the world of geometry, of mathematics.
The right hand side lives in the world of physics, of matter and movement.
And so perhaps the most powerful ingredient of the equation is this very simple equal sign here, these two lines that actually are connecting the two worlds, and it's quite appropriate they're two lines because it's two-way traffic.
Matter tells space and time to curve, space and time tells matter to move.
When Einstein presented his great theory, few people understood it.
He needed a way to prove to the world that the counterintuitive features of his theory were real.
The general theory of relativity made predictions of things which looked really strange.
For example, the idea that light bends when it passes near a very heavy body.
No one had ever looked for that.
No one had ever observed it.
Einstein was desperate, desperate to get astronomers to make that test.
Einstein's theory predicts that when light from a distant star travels close to the sun, the warped space around the sun bends the light's path.
In May 1919, the English astronomer Arthur Eddington traveled to the African island of Principe to record images that would show this phenomenon.
What Eddington had been able to do was take photographs of stars during a total eclipse of the sun so the moon blocked most of the brightness of the sun and little pinpricks of light could be seen around the sun Otherwise, it would be lost in the glare And Eddington and his colleagues were able to measure that the appearance of those stars had been shifted compared to where they would have been had that big mass of the sun not been deflecting that light from far away.
So Eddington's able to show that Einstein's general relativity theory is right and a revolution in science has been accomplished.
When the eclipse experiments prove Einstein's theory right, he rockets to fame.
Not just because he's explained a new way of looking at the universe, but at the end of World War I, you had the predictions of a German scientist be proven right by some British astronomers, and it becomes headlines across the world.
The New York Times says, "Lights all askew at the heavens, men of science more or less agog.
" This is back when newspapers knew how to write great headlines.
But Einstein kind of loves this fact that he is now an icon of science.
Einstein becomes a worldwide celebrity, the icon of genius we still recognize today.
The only person who was more widely known was Charlie Chaplin, and they got on like a house on fire.
Chaplin said, "The reason they all love me "is because they understand everything I do, "and the reason they love you "is that they don't understand anything you do.
Can you explain that?" And Einstein said But in 1930s Berlin, the Nazi party is gaining power.
As a Jewish scientist, Einstein becomes increasingly caught up in the political turmoil.
Einstein's theories became a target.
They were deemed aesthetically repugnant to a kind of Aryan sensibility.
So people attacked not just Einstein the Jewish scientist, but they would actually have people denouncing general relativity.
In January, Nobel Prize mathematician Albert Einstein visited California He begins to make trips to America, where he is welcomed with open arms.
Germany's loss, America's gain.
And in 1933, he settles in Princeton with his second wife Elsa, taking up a position at the Institute for Advanced Study.
Today, the Institute is headed by Professor Robbert Dijkgraaf.
He basically was still very much by himself, just actually as he was in Berlin, just concentrating on his deep ideas and struggling with understanding the universe.
Of course, his office was here.
At the Institute, Einstein worked to unify his theory of gravity with the other laws of physics.
With Einstein, you see this phenomena you see with many great scientists That they climb this very high mountain and instead of celebrating their success, they're privileged to see a much wider landscape, and they see all these mountains behind it.
And I think he was very much aware how much still there was to be done.
Till the very last days of his life, he was trying to push these equations and find a description of nature, all of nature, in terms of the geometry of space and time.
But general relativity was fading from mainstream science.
Physics was now focused on the quantum theory of atoms and tiny particles, a theory incompatible with Einstein's ideas, but one that could be tested in the lab.
Most of general relativity was then beyond the reach of experiment.
When Einstein died in 1955, age 76, his theory was seen as one with little hope of future discovery.
The best theories in physics always take us to places where the people who invented them didn't imagine.
And a truly wonderful theory like general relativity predicts all sorts of things that Einstein didn't conceive of.
The theory has a life of its own.
We understand general relativity much better right now than Albert Einstein ever did.
Liftoff of space shuttle Discovery with the Hubble space telescope, our window on the universe.
Today, 100 years after general relativity was first presented Telescopes released, okay, thank you.
new technology is allowing us to explore the most remarkable predictions of the theory: an expanding universe, black holes, ripples in spacetime, and perhaps the most bizarre, the idea that not just space, but time itself is distorted by heavy objects.
To prove it, a team of physicists is carrying out a remarkable experiment.
They're using two atomic clocks that are in near perfect sync, accurate to a billionth of a second.
The master clock remains at sea level while they take the second clock to the top of New Hampshire's Mount Sunapee.
General relativity tells us that as you move away from the mass of the planet, time should speed up.
After four days at the top of the mountain, the test clock is taken back to the lab for comparison.
There, they compare it to the sea level master clock.
We'll put that one into Channel A.
Four days ago, they were ticking in unison.
Master clock in Channel B.
But what about now? You guys ready? This is it right here.
The time interval counter is gonna show us the time difference between these two clock ticks.
20 nanoseconds.
You can see the time difference between them represented here graphically of the clock that was up at the mountain for four days and our master clock.
Gravity, the distortion of space and time, becomes weaker as you move away from the surface of the planet.
So while the test clock was up the mountain, time sped up.
It's now 20 nanoseconds, 20 billionths of a second, ahead of the sea level clock, This is really awesome.
This distortion of time has surprising consequences.
The Global Positioning System, something we all take for granted, wouldn't work without taking this into account.
The engineers who built the GPS system we use every day to pinpoint locations had to ensure it adjusted for the time difference between clocks on satellites and receivers on the ground.
If they didn't, GPS would be off by six miles every day.
Your GPS units use the results of general relativity.
When you navigate in your car, you perhaps should give a word of thanks to Uncle Albert.
Of all general relativity's predictions that new technology has allowed us to explore, there's one that's straight out of science fiction: a black hole.
Everything that we're familiar with in ordinary life is made from matter.
But not black holes.
Black holes are made from warped space and time and nothing else.
A black hole is an object that is spherical, like a star or like the Earth, with a sharp boundary called the horizon through which nothing can come out.
So it casts a shadow on whatever is behind it.
It's just a black, black shadow, unbelievably black.
This simulation shows the distortion of starlight around a black hole.
Even though Einstein knew his theory predicted black holes, he found it hard to believe they would really exist in nature.
In the 1960s, Professor Kip Thorne worked on the mathematical concept of black holes.
The idea made sense on paper, and he began to feel that these science fiction-like objects might actually be real.
Must be here somewhere, it's in one of these piles.
Kip Thorne made a bet with fellow physicist Stephen Hawking about whether or not a strong source of x-rays known as Cygnus X-1 was in fact a black hole.
I think it's in here.
Yeah, here we go, relativity, stars and black holes.
Yeah, there it is.
So that is a copy of the famous bet.
"Stephen Hawking bets a one-year subscription "to Penthouse magazine "against Kip Thorne's wager of a four-year subscription "to a political magazine called Private Eye "that Cygnus X-1 does not contain a black hole of mass "above the Chandrasekhar Limit.
It's witnessed this 10th day of December 1974.
" Stephen Hawking had a terribly deep investment in it actually being a black hole, and so he made the bet against himself as an insurance policy that at least he would get something out of it if Cygnus X-1 turned out not to be a black hole.
The evidence mounted thereafter over the period of the '70s and '80s, and in June 1990, Stephen snuck into my office and signed off on the bet, that finally, the evidence was absolutely overwhelming that Cygnus X-1 really is a black hole.
And Penthouse magazine arrived.
He sent me the British version of Penthouse, which was ever so much more raunchy than the American Penthouse, actually.
Enough to make my face turn red when I received it at first.
Today, we have evidence suggesting that there are millions of black holes in our galaxy alone.
But perhaps the most profound prediction of general relativity is that our universe had a hot, dense beginning that we call the big bang.
The discovery that distant galaxies are moving away from us and that there's a background radiation permeating space provided evidence for the big bang and a universe that's growing.
With this picture of an expanding universe, there were natural questions.
Is the universe slowing down as it expands? Is it so dense that someday, it will come to a halt and collapse? Will the universe come to an end? These seemed like good questions.
To find answers, in the 1990s, Saul Perlmutter and his team observed exploding stars, called supernovae, to track the growth of the universe.
When we made the measurement, we discovered that the universe isn't slowing down enough to come to a halt.
In fact, it's not slowing at all; it's speeding up! The universe is expanding faster and faster.
But what's pushing it? In order to explain the acceleration of the universe within Einstein's theory of general relativity, we're considering an energy spread throughout all of space that we've never seen before.
We don't know what it is.
We call it dark energy.
And, if so, it would require something like 70% of all the stuff of the universe to be in this form of previously unknown dark energy.
So this is a lot to swallow, and you might imagine that at that point, you should go back and revisit your theory.
The problem is that Einstein's theory is so elegant, and it predicts many, many, many digits of precision, that it's very, very difficult to come up with any other theory.
There is one final prediction of general relativity that remains untested: gravitational waves.
There are huge things in the universe happening, like black holes colliding or stars exploding, and they create these gravitational waves Waves in the shape of space and time that travel through the universe at the speed of light.
And so right now, the space around me is being squeezed and stretched by gravitational waves just getting here from, let's say, two black holes colliding a billion light years away.
But the squeezing and stretching is so minute, I absolutely could not personally detect it.
And so what we're trying to do is build an instrument that can.
In Louisiana and Washington state, a vast experiment called LIGO is in the final phases of calibration.
It's hoped that laser beams traveling two-and-a-half miles between precisely aligned mirrors will measure the squeezing of space caused by gravitational waves.
This could open up an entirely new window on the universe.
For 100 years, general relativity has been proven to be correct time and time again.
But Einstein himself knew that his great theory had limits.
It remains incompatible with the quantum world of tiny atomic particles.
Here at the Institute for Advanced study, where Einstein worked, the world's leading theoretical physicists are trying to solve the problem Einstein never could: finding a single set of rules that applies to both the cosmic and atomic scales.
A unified theory.
The Holy Grail of physics.
We are now in what at this time is the school of physics.
So here, people are still struggling with many of the same issues that Einstein would struggle and are still trying to capture the laws of the universe from the very small to the very large in a single equation.
And it's still blackboards that are the weapon of choice.
The brightest minds of the world are coming here to work 24 hours, seven days a week, struggling to grasp the great mysteries of the universe.
And I think we are still driven by the same dream: that at some point, we can capture everything in elegant mathematics.
100 years after Einstein transformed our understanding of nature, the stage is set for the next revolution.
When we finally move beyond Einstein, it might be another singular genius that comes along Someone struggling in a poor school in Kenya right now that we don't know about.
Or it might be 20 different people with 20 different points of view gradually building brick-by-brick to finally figure out a more comprehensive view that includes general relativity in it.
I think the most important thing that you learn from Einstein is just the power of an idea.
If it's correct, you know, it's just unstoppable.
It's extremely encouraging that he was able with pure thought to solve the riddle of the universe.
Once we had general relativity, the world changed completely.
Our point of view on the world changed completely.
I mean, the origin of the universe is a prediction straight out of general relativity.
We didn't have that before.
I often wonder what Einstein would make of today's theoretical physics.
I think he would really be saying, you know, "Get on with it, get the right story, get the details right.
" You know, you have the huge universe, and it obeys certain laws of nature, but where in the universe are these laws actually discovered? Where are they studied? And then you go to this tiny planet and there's this one individual, Einstein, who captures this.
And now there's a small group of people walking in his footsteps and trying to push it further.
And I often feel, well, it's this small part of the universe that actually is reflecting upon itself, that tries to understand itself.
It feels familiar, but it's far stranger than anyone ever imagined.
And yet, one man's brilliant mind tamed it.
Gravity.
Using simple thought experiments, Albert Einstein made an astonishing discovery: time and space are shaped by matter.
You get rid of this force of gravity, and instead, we have curvature of spacetime.
Right now, the space around me is being squeezed and stretched.
He called it the "General Theory of Relativity.
" How did one person, working almost entirely alone, change everything we thought we knew about the universe? Einstein is toiling as the world seems to fall apart.
He was able with pure thought to solve the riddle of the universe.
"Inside Einstein's Mind," right now on NOVA.
Gravity.
The most familiar yet most mysterious of nature's forces.
100 years ago, Albert Einstein made a mind-blowing discovery: what we feel as gravity is in fact the push and pull of space and time itself.
He called his idea "general relativity.
" It is perhaps the most remarkable feat of thinking about nature to come from a single mind.
General relativity is undoubtedly one of the greatest scientific theories ever conceived.
It's a theory of space, time, and gravity.
One mathematical sentence, and from it, you can derive the understanding of the entire universe on the largest scales, and that is beautiful.
Only now, a century after it was first proposed, do we have the technology to explore the extremes of Einstein's great theory.
Supermassive black holes at the center of galaxies.
Waves of gravity that distort space and time.
The evolution of our entire universe.
How did a concept that explains so much come from the mind of one man? Einstein had a magical talent.
He could take a hard, physical problem and boil it down to a powerful visual image, a thought experiment.
Suddenly he realizes, "This is how the world works.
All this abstract nonsense is the correct theory of reality.
" To gain an insight into Einstein's mind and the true wonder of general relativity, we need to trace the crucial thought experiments that led to his great breakthrough.
The seeds for his ideas were planted when he was just a child.
Einstein grew up in a small house in Munich, in southern Germany.
His unique personality was evident early on.
Like many great innovators, Einstein was a rebel, a loner, but deeply curious.
He was slow in learning to speak as a child, so slow that his parents consulted a doctor, but he later said that that's maybe why he thought in visual thought experiments.
His sister remembers him building little card towers using playing cards.
He was a daydreamer, but he was deeply persistent.
Einstein's father, Hermann, manufactured electrical equipment.
He nurtured his son's interest in science.
On one occasion, he brought him a compass.
Now, you and I maybe remember getting a compass when we were kids, and we were like, "Oh look, the needle twitches and points north," but then we're on to something else, like, "Oh look, there's a dead squirrel.
" But for Einstein, after getting that compass, he developed a lifelong devotion to understanding how things can be forced to move even though nothing's touching them.
The young Einstein became gripped by a desire to understand the underlying laws of nature.
He developed a unique way of thinking about the physical world inspired by his favorite book.
The book Einstein loved told little stories, like what it'd be like to travel through space or go through an electrical wire.
And it made Einstein think visually.
These imagined situations that we often call "thought experiments" became a defining feature of Einstein's thinking.
One of the critical thought experiments that Einstein began to play with very young, around the age of 16, was trying to imagine what would happen if he could catch up with a light wave.
It's one thing to imagine a light wave zooming past him at some seemingly impossible speed, but what if he could somehow just propel himself really quickly? What would it look like if he could catch up with that light wave? What would he see? He said it caused him to walk around in such anxiety, his palms would sweat.
Now, you and I may remember what was causing our palms to sweat at age 16, and it was not a light beam.
But that's why he's Einstein.
This dream-like thought about the nature of light was Einstein's first step on the path to his great theory.
It stayed with him throughout his time at school and college.
He was extremely gifted in science and math as a young person and very bad at other classes, mostly because he kept cutting class and being very rude to his teachers.
Many teachers from his high school days on were convinced he'd never amount to anything.
He was a discipline problem, and he was bad news.
He applies to the second best university in Zurich, the Zurich Polytech, and gets rejected.
I'd love to meet the admissions director who rejected Albert Einstein.
But eventually he gets in, and he does moderately well, but not good enough to get a teaching fellowship.
And so he ends up at the Bern Swiss patent office as a third class examiner.
Undaunted by his university results, Einstein started work at the patent office in 1902, age 23.
Here, his job was to assess the originality of new devices.
He was immersed in the kinds of technical details that he'd been fascinated by as a very young kid.
And here he was, sitting in the kind of wave of the modern age.
This was the era of electrification.
So all the latest clever ideas for switching technology, for coordinating clocks in particular, those were all passing through his office.
Time zones had recently been introduced in central Europe, and accurately synchronizing clocks was a major challenge of the day.
Switzerland was a world leader in time technology.
Dozens of patents to link clocks passed through Einstein's office.
He could whip through these patent applications, and then out of his drawer, he'd pull his physics notes, and his boss was very indulgent and would sort of turn a blind eye as Einstein was doing his theories in his spare time.
It's really important to remember that theoretical physics was new when Einstein was a young man.
You could do quite a lot of this work by reading a relatively small number of science journals and making the calculations yourself.
Einstein's world in 1905 was dominated by two kinds of physics.
One was about 200 years old, founded by Isaac Newton, a British natural philosopher.
For Newton, all there is in the world is matter moving.
Newton showed that the motion of falling apples and orbiting planets are governed by the same force: gravity.
His equations are so effective, we still use them today to send probes to the farthest reaches of the solar system.
The other important theory of Einstein's day covered electricity and magnetism.
That branch of physics had been revolutionized in 1865 by the Scottish physicist James Clerk Maxwell.
Maxwell's theory describes light as an electromagnetic wave that travels at a fixed speed.
In Newton's world, the speed of light is not fixed.
Einstein could see that there's a contradiction between Newton and Maxwell.
They just don't fit together.
And one of the things Einstein hated hated Was contradiction.
If there's one kind of physics that says this and another kind of physics that says that and they're different, that's a sign that something's gone wrong and it needs fixing.
For months, Einstein wrestles with the problem.
Eventually, to resolve this contradiction, he focuses on a key element of speed: time.
He realized that any statement about time is simply a question about what is simultaneous.
For example, if you say the train arrives at 7:00, that simply means that it gets to the platform simultaneous with the clock going to 7:00.
In a brilliant thought experiment, he questions what "simultaneous" actually means and sees that the flow of time is different for an observer that is moving versus one that is standing still.
He imagines a man standing on a railway platform.
Two bolts of lightning strike on either side of him.
The man is standing exactly halfway between them and the light from each strike reaches his eyes at exactly same moment.
For him, the two strikes are simultaneous.
Then Einstein imagines a woman on a fast-moving train, Traveling at close to the speed of light, what would she see? As the light travels out from the strikes, the train is moving towards one and away from the other.
Light from the front strike reaches her eyes first.
For the woman on the train, time elapses between the two strikes.
For the man on the platform, there is no time between the strikes.
This simple thought has mind-blowing significance.
Simultaneity, and the flow of time itself, depends on how you're moving.
If there's no such thing as simultaneity, then there's no such thing as absolute time everywhere throughout the universe, and Isaac Newton was wrong.
This concept that time, and space as well, are relative became known as special relativity.
It led to remarkable results, such as the famous equation relating energy to mass.
Einstein published this article in 1905 to exactly no acclaim.
Most people ignored it.
This was not setting the world on fire.
Two years go by before a very eminent physicist, Johannes Stark, invites Einstein to write a review article on Einstein's own work, precisely because no one was paying attention.
And he begins thinking about ways to generalize and to push his own results from 1905.
What if he considers not only a train moving at a fixed speed past the platform? What if that train begins to speed up or slow down? What if there's acceleration? Adding acceleration to the equations was his first task.
Then there was that mysterious Newtonian force of gravity to contend with.
In Newton's theory, gravity is a force that acts instantaneously.
But special relativity says that's impossible Nothing can travel faster than light.
What Newton's theory tells you is that suppose the sun were to disappear, the orbit of the earth should change at that very moment.
But the notion of "at that very moment" in two different places is exactly one of these notions that special relativity has told you isn't a good physics notion.
So you've now got this challenge of trying to work out how to take the success of Newton's theory of gravity but fit it into this new special relativistic picture.
It was only when Einstein began to understand the link between gravity and acceleration that things began to fall into place.
We all know that when we are accelerated, and of course now we have cars and airplanes to give us the physical feeling, if you're in an airplane and it's taking off, you are pushed back in your chair, you feel actually kind of a force pushing you back, which feels very similar to the force of gravity.
But you need the brilliance of Einstein to explain why they are related.
Suddenly, he hits upon what he describes as the happiest thought of his life.
If gravity and acceleration feel the same, perhaps they are the same.
Again, he examines the idea in a beautiful thought experiment.
He imagines a man in a box floating weightlessly in a distant region of space in zero gravity.
Suddenly, the man stops floating and accelerates downward until he's standing in the box.
What has happened? Either the box is now close to a planet and the force of gravity has pulled the man to the floor, or someone has attached a rope and the box is now being pulled continuously and accelerated upwards.
So which is it? Gravity? Or acceleration? Without being able to see outside, the man can't tell what's causing his fall to the floor.
Einstein realized there is no way to tell the difference between sitting in a gravitational field and being accelerated.
These are equivalent situations The fact that these two effects are the same, give the same result, means that gravity is acceleration.
It's not just like acceleration; it's the same thing.
It's a big breakthrough.
Einstein's theory of special relativity worked for motion at a constant speed.
By extending his ideas to acceleration, he could begin to formulate a new theory of gravity.
In 1912, Einstein is living in Zurich with his wife Mileva and two young sons, Hans and Eduard.
The academic world had realized the importance of special relativity, and his career had taken off.
He's now a professor at the esteemed Swiss Federal Institute of Technology, but spends as much time as possible working on his theory.
He needs mathematics that describes how objects move in space and time and soon realizes that the best tool for the job is a strange but powerful concept called "spacetime.
" If I think of space, I know that I can find anything if I know where it is north-south, east-west, and up-down, three points.
But that doesn't mean I can find it, because I also have to know where it is in time.
And so if we start to think, to know everything about an event in the universe, I have to know not just its spatial coordinates, but also its time coordinate.
I can begin to think about where it is in spacetime.
Imagine a camera filming an action, capturing each moment in time as a single frame.
Einstein basically tells us, "Think of the movie reel.
" So you have all these little pictures.
Now, cut them apart one by one and stack them on top of each other, you get this pile.
And if you go up in the pile, you go up in time.
And now kind of glue them all together into one big block, and that block has both space and time, and that's the spacetime continuum.
It's almost looking at a movie not frame by frame, but seeing the whole movie at once.
They would now be kind of two strands going up in space and time, and they would be kind of spaghetti strands.
In fact, we all are spaghetti strands moving in this spacetime.
Einstein feels that spacetime is the natural arena in which his theory of relativity should play out.
But now he needs sophisticated mathematics.
By your standard or mine, Einstein was good at math.
He was Einstein.
But he was not really a mathematician per se.
He didn't prove theorems, he didn't pore over math books.
He was a physicist.
He did thought experiments.
He thought of very tangible, concrete situations and what would happen.
So when it came time for him to really bear down to the absolute cutting edge mathematics of his day, he required help.
At university, Einstein had skipped the geometry classes, letting his friend Marcel Grossman take notes for him.
Grossman had excelled in geometry and was now chairman of the math department.
He suggests Einstein uses advanced mathematics in which the shape of space and time could be curved.
Because spacetime has a geometry, he thinks to himself, "Well, maybe it's the actual shape of spacetime itself that is giving rise to gravity.
" After months of work, Einstein has an extraordinary idea.
"What if spacetime is shaped by matter, and that's what we feel as gravity?" In struggling to figure out what causes gravity then, Einstein has this great insight.
It is simply that a mass distorts the shape of spacetime around it.
So you get rid of this force of gravity, and instead we have curvature of spacetime.
In Einstein's universe then, if space were empty, it would be flat.
There'd be nothing going on.
But as soon as you put objects down, they warp the space and time around them, and that causes a deviation of the geometry so that now things start moving.
Everything wants to move as simple as possible through space and time.
But Einstein tells us that mass sculpts space and time, and it's the curved motion through this sculpture that's the force of gravity.
We have this feeling that the reason I can feel pressure on the soles of my feet, that the reason things are going to drop when I throw them, are because there's a force attracting us down to the center of the earth.
What general relativity tells you is that's not the right way to think about what's going on there.
What's really going on is that your natural path in spacetime would take you to the center of the earth, and what's actually happening is the floor is getting in the way, it's pushing you upwards.
When we look at it, we go, "Ah, the force of gravity" But Einstein says, "No, no, no, the curvature of spacetime.
" It's a stunning insight.
Just as an ant might feel forces pulling it left and right as it walks over crumpled paper when it's simply the shape of a surface dictating its path, Einstein saw that what we feel as the force of gravity is in fact the shape of the spacetime we're moving through.
Einstein now has everything he needs to formulate his final theory of gravity.
But he makes a critical mistake.
He misinterprets one of his equations, and unaware of his error, continues working on incorrect ideas.
The point at which Einstein is going to give the most essential equations of the theory, Einstein considers something like them and then says, "Ah, but these don't work," and then writes down the wrong equations.
What follows are alternations of confidence and despair as he convinces himself that everything was fine with this theory, and then he realizes that things aren't so good with the theory.
It is a long, dark period for Einstein as he struggles to reconcile himself with a theory that is just not working.
Two years later, Einstein is in Berlin.
At just 36 years old, he has one of the most prestigious positions in physics.
But he is still struggling with his theory.
By 1915, he'd reached the pinnacle of the profession.
He's in the Prussian Academy and a professor at the University of Berlin.
But his marriage is falling apart, his wife and his two kids have moved back to Switzerland, so he's pacing around almost all alone in this apartment in Berlin.
And now he has a competitor.
Einstein had enthusiastically shared his ideas with the brilliant mathematician David Hilbert.
Hilbert was so impressed, he decided to work on the theory himself.
Einstein is now in a race to the finish with one of the world's best mathematicians.
This is unfolding in a remarkably dramatic period in history.
World War I has begun to ravage central Europe.
Einstein is not just toiling in the abstract; he's toiling as the world seems to fall apart.
By November 1915, Einstein is scheduled to present his work in a series of four weekly lectures at the esteemed Prussian Academy.
But he's struggling to formulate his ideas.
In the midst of these challenges, letters arrive from his wife in Zurich pressing the issue of his financial obligations to his family and discussing contact with his sons.
As his lectures begin, his theory is still far from complete.
The pressure on Einstein is huge.
He would give a lecture, revise it, give it again.
Spot mistakes, correct them, get up on the podium, explain what was wrong in the previous week's lecture, correct it and then move on, and then do that again and again for four weeks running.
His work to convince them of the truth of this absolutely radical new theory of relativity that he was proposing is one of the most intense periods of work in the history of science.
Somehow, he's able to focus on his theory with an incredible intensity, and he makes his breakthrough.
He tests his equations on a problem that Newton's theory of gravity couldn't solve: the orbit of Mercury.
Mercury's path around the sun has an anomaly that Newton's theory can't explain: it deviates slightly each time it goes round.
Einstein calculates the orbit with his new equations.
The answer is correct, exactly what astronomers had observed.
He'd found the final equations for his general theory of relativity.
You have to think about the hubris of being Albert Einstein.
He had already thrown out Newtonian mechanics with special relativity, and then he had gone off on his little personal quest to incorporate gravity.
And at the end of the day, he boils it down to a prediction for a number that had been observed: the procession of the orbit of Mercury.
And, miraculously, when the pages of algebra work out to their end, you get the right answer.
And suddenly, it's not just playing with equations anymore; he realizes this is how the world works.
All this abstract nonsense is the correct theory of reality.
Einstein is at last able to present a successful theory.
That's a triumphant moment, one of the great moments in the history of physics, and, for Einstein, a victory very much against the odds, and he'd won.
On the 25th of November 1915, Einstein lays out his findings in his climactic fourth lecture at the Prussian Academy.
He presents general relativity.
The theory can be written as a single equation.
It condenses sprawling complexities into a beautifully compact set of symbols.
So the formula is really simple: G-mu-nu equals G for the shape of spacetime and T for the distribution of mass and energy.
So this very simple formula captures all of Einstein general relativity.
It's a beautiful, simple equation but it's a lot of work to unpack the symbols, the mathematical symbols, and see how in this very simple formula, the whole geometry of the universe is hidden.
It's kind of an acquired taste to see the beauty.
It's also a signature formula for Einstein.
The true mark of his genius is that he combines two elements that actually live in different universes.
The left hand side lives in the world of geometry, of mathematics.
The right hand side lives in the world of physics, of matter and movement.
And so perhaps the most powerful ingredient of the equation is this very simple equal sign here, these two lines that actually are connecting the two worlds, and it's quite appropriate they're two lines because it's two-way traffic.
Matter tells space and time to curve, space and time tells matter to move.
When Einstein presented his great theory, few people understood it.
He needed a way to prove to the world that the counterintuitive features of his theory were real.
The general theory of relativity made predictions of things which looked really strange.
For example, the idea that light bends when it passes near a very heavy body.
No one had ever looked for that.
No one had ever observed it.
Einstein was desperate, desperate to get astronomers to make that test.
Einstein's theory predicts that when light from a distant star travels close to the sun, the warped space around the sun bends the light's path.
In May 1919, the English astronomer Arthur Eddington traveled to the African island of Principe to record images that would show this phenomenon.
What Eddington had been able to do was take photographs of stars during a total eclipse of the sun so the moon blocked most of the brightness of the sun and little pinpricks of light could be seen around the sun Otherwise, it would be lost in the glare And Eddington and his colleagues were able to measure that the appearance of those stars had been shifted compared to where they would have been had that big mass of the sun not been deflecting that light from far away.
So Eddington's able to show that Einstein's general relativity theory is right and a revolution in science has been accomplished.
When the eclipse experiments prove Einstein's theory right, he rockets to fame.
Not just because he's explained a new way of looking at the universe, but at the end of World War I, you had the predictions of a German scientist be proven right by some British astronomers, and it becomes headlines across the world.
The New York Times says, "Lights all askew at the heavens, men of science more or less agog.
" This is back when newspapers knew how to write great headlines.
But Einstein kind of loves this fact that he is now an icon of science.
Einstein becomes a worldwide celebrity, the icon of genius we still recognize today.
The only person who was more widely known was Charlie Chaplin, and they got on like a house on fire.
Chaplin said, "The reason they all love me "is because they understand everything I do, "and the reason they love you "is that they don't understand anything you do.
Can you explain that?" And Einstein said But in 1930s Berlin, the Nazi party is gaining power.
As a Jewish scientist, Einstein becomes increasingly caught up in the political turmoil.
Einstein's theories became a target.
They were deemed aesthetically repugnant to a kind of Aryan sensibility.
So people attacked not just Einstein the Jewish scientist, but they would actually have people denouncing general relativity.
In January, Nobel Prize mathematician Albert Einstein visited California He begins to make trips to America, where he is welcomed with open arms.
Germany's loss, America's gain.
And in 1933, he settles in Princeton with his second wife Elsa, taking up a position at the Institute for Advanced Study.
Today, the Institute is headed by Professor Robbert Dijkgraaf.
He basically was still very much by himself, just actually as he was in Berlin, just concentrating on his deep ideas and struggling with understanding the universe.
Of course, his office was here.
At the Institute, Einstein worked to unify his theory of gravity with the other laws of physics.
With Einstein, you see this phenomena you see with many great scientists That they climb this very high mountain and instead of celebrating their success, they're privileged to see a much wider landscape, and they see all these mountains behind it.
And I think he was very much aware how much still there was to be done.
Till the very last days of his life, he was trying to push these equations and find a description of nature, all of nature, in terms of the geometry of space and time.
But general relativity was fading from mainstream science.
Physics was now focused on the quantum theory of atoms and tiny particles, a theory incompatible with Einstein's ideas, but one that could be tested in the lab.
Most of general relativity was then beyond the reach of experiment.
When Einstein died in 1955, age 76, his theory was seen as one with little hope of future discovery.
The best theories in physics always take us to places where the people who invented them didn't imagine.
And a truly wonderful theory like general relativity predicts all sorts of things that Einstein didn't conceive of.
The theory has a life of its own.
We understand general relativity much better right now than Albert Einstein ever did.
Liftoff of space shuttle Discovery with the Hubble space telescope, our window on the universe.
Today, 100 years after general relativity was first presented Telescopes released, okay, thank you.
new technology is allowing us to explore the most remarkable predictions of the theory: an expanding universe, black holes, ripples in spacetime, and perhaps the most bizarre, the idea that not just space, but time itself is distorted by heavy objects.
To prove it, a team of physicists is carrying out a remarkable experiment.
They're using two atomic clocks that are in near perfect sync, accurate to a billionth of a second.
The master clock remains at sea level while they take the second clock to the top of New Hampshire's Mount Sunapee.
General relativity tells us that as you move away from the mass of the planet, time should speed up.
After four days at the top of the mountain, the test clock is taken back to the lab for comparison.
There, they compare it to the sea level master clock.
We'll put that one into Channel A.
Four days ago, they were ticking in unison.
Master clock in Channel B.
But what about now? You guys ready? This is it right here.
The time interval counter is gonna show us the time difference between these two clock ticks.
20 nanoseconds.
You can see the time difference between them represented here graphically of the clock that was up at the mountain for four days and our master clock.
Gravity, the distortion of space and time, becomes weaker as you move away from the surface of the planet.
So while the test clock was up the mountain, time sped up.
It's now 20 nanoseconds, 20 billionths of a second, ahead of the sea level clock, This is really awesome.
This distortion of time has surprising consequences.
The Global Positioning System, something we all take for granted, wouldn't work without taking this into account.
The engineers who built the GPS system we use every day to pinpoint locations had to ensure it adjusted for the time difference between clocks on satellites and receivers on the ground.
If they didn't, GPS would be off by six miles every day.
Your GPS units use the results of general relativity.
When you navigate in your car, you perhaps should give a word of thanks to Uncle Albert.
Of all general relativity's predictions that new technology has allowed us to explore, there's one that's straight out of science fiction: a black hole.
Everything that we're familiar with in ordinary life is made from matter.
But not black holes.
Black holes are made from warped space and time and nothing else.
A black hole is an object that is spherical, like a star or like the Earth, with a sharp boundary called the horizon through which nothing can come out.
So it casts a shadow on whatever is behind it.
It's just a black, black shadow, unbelievably black.
This simulation shows the distortion of starlight around a black hole.
Even though Einstein knew his theory predicted black holes, he found it hard to believe they would really exist in nature.
In the 1960s, Professor Kip Thorne worked on the mathematical concept of black holes.
The idea made sense on paper, and he began to feel that these science fiction-like objects might actually be real.
Must be here somewhere, it's in one of these piles.
Kip Thorne made a bet with fellow physicist Stephen Hawking about whether or not a strong source of x-rays known as Cygnus X-1 was in fact a black hole.
I think it's in here.
Yeah, here we go, relativity, stars and black holes.
Yeah, there it is.
So that is a copy of the famous bet.
"Stephen Hawking bets a one-year subscription "to Penthouse magazine "against Kip Thorne's wager of a four-year subscription "to a political magazine called Private Eye "that Cygnus X-1 does not contain a black hole of mass "above the Chandrasekhar Limit.
It's witnessed this 10th day of December 1974.
" Stephen Hawking had a terribly deep investment in it actually being a black hole, and so he made the bet against himself as an insurance policy that at least he would get something out of it if Cygnus X-1 turned out not to be a black hole.
The evidence mounted thereafter over the period of the '70s and '80s, and in June 1990, Stephen snuck into my office and signed off on the bet, that finally, the evidence was absolutely overwhelming that Cygnus X-1 really is a black hole.
And Penthouse magazine arrived.
He sent me the British version of Penthouse, which was ever so much more raunchy than the American Penthouse, actually.
Enough to make my face turn red when I received it at first.
Today, we have evidence suggesting that there are millions of black holes in our galaxy alone.
But perhaps the most profound prediction of general relativity is that our universe had a hot, dense beginning that we call the big bang.
The discovery that distant galaxies are moving away from us and that there's a background radiation permeating space provided evidence for the big bang and a universe that's growing.
With this picture of an expanding universe, there were natural questions.
Is the universe slowing down as it expands? Is it so dense that someday, it will come to a halt and collapse? Will the universe come to an end? These seemed like good questions.
To find answers, in the 1990s, Saul Perlmutter and his team observed exploding stars, called supernovae, to track the growth of the universe.
When we made the measurement, we discovered that the universe isn't slowing down enough to come to a halt.
In fact, it's not slowing at all; it's speeding up! The universe is expanding faster and faster.
But what's pushing it? In order to explain the acceleration of the universe within Einstein's theory of general relativity, we're considering an energy spread throughout all of space that we've never seen before.
We don't know what it is.
We call it dark energy.
And, if so, it would require something like 70% of all the stuff of the universe to be in this form of previously unknown dark energy.
So this is a lot to swallow, and you might imagine that at that point, you should go back and revisit your theory.
The problem is that Einstein's theory is so elegant, and it predicts many, many, many digits of precision, that it's very, very difficult to come up with any other theory.
There is one final prediction of general relativity that remains untested: gravitational waves.
There are huge things in the universe happening, like black holes colliding or stars exploding, and they create these gravitational waves Waves in the shape of space and time that travel through the universe at the speed of light.
And so right now, the space around me is being squeezed and stretched by gravitational waves just getting here from, let's say, two black holes colliding a billion light years away.
But the squeezing and stretching is so minute, I absolutely could not personally detect it.
And so what we're trying to do is build an instrument that can.
In Louisiana and Washington state, a vast experiment called LIGO is in the final phases of calibration.
It's hoped that laser beams traveling two-and-a-half miles between precisely aligned mirrors will measure the squeezing of space caused by gravitational waves.
This could open up an entirely new window on the universe.
For 100 years, general relativity has been proven to be correct time and time again.
But Einstein himself knew that his great theory had limits.
It remains incompatible with the quantum world of tiny atomic particles.
Here at the Institute for Advanced study, where Einstein worked, the world's leading theoretical physicists are trying to solve the problem Einstein never could: finding a single set of rules that applies to both the cosmic and atomic scales.
A unified theory.
The Holy Grail of physics.
We are now in what at this time is the school of physics.
So here, people are still struggling with many of the same issues that Einstein would struggle and are still trying to capture the laws of the universe from the very small to the very large in a single equation.
And it's still blackboards that are the weapon of choice.
The brightest minds of the world are coming here to work 24 hours, seven days a week, struggling to grasp the great mysteries of the universe.
And I think we are still driven by the same dream: that at some point, we can capture everything in elegant mathematics.
100 years after Einstein transformed our understanding of nature, the stage is set for the next revolution.
When we finally move beyond Einstein, it might be another singular genius that comes along Someone struggling in a poor school in Kenya right now that we don't know about.
Or it might be 20 different people with 20 different points of view gradually building brick-by-brick to finally figure out a more comprehensive view that includes general relativity in it.
I think the most important thing that you learn from Einstein is just the power of an idea.
If it's correct, you know, it's just unstoppable.
It's extremely encouraging that he was able with pure thought to solve the riddle of the universe.
Once we had general relativity, the world changed completely.
Our point of view on the world changed completely.
I mean, the origin of the universe is a prediction straight out of general relativity.
We didn't have that before.
I often wonder what Einstein would make of today's theoretical physics.
I think he would really be saying, you know, "Get on with it, get the right story, get the details right.
" You know, you have the huge universe, and it obeys certain laws of nature, but where in the universe are these laws actually discovered? Where are they studied? And then you go to this tiny planet and there's this one individual, Einstein, who captures this.
And now there's a small group of people walking in his footsteps and trying to push it further.
And I often feel, well, it's this small part of the universe that actually is reflecting upon itself, that tries to understand itself.