The National Science Foundation.
( clock ticking )
MAN: When we think of E equals m c-squared,
we have this vision of Einstein
as an old, wrinkly man with white hair.
MAN 2: E equals m c-squared is not about an old Einstein.
It's actually about a young, energetic, dynamic,
even a sexy Einstein.
ACTOR AS EINSTEIN: What would I see if I rode on a beam of light?
MAN: Perhaps some sort
of electrical force is emanating
outwards from the wire.
What?
MAN: Faraday, my dear boy,
electricity flows through a wire,
not sideways to it.
You see, John?
You see?
MAN: It is my great ambition to demonstrate
that nature is a closed system;
that in any transformation,
no amount of matter, no mass, is ever lost and none is gained.
The people...
OuĂą est Lavoisier?
It is they who will determine right and wrong.
( both laughing )
MAN: Emilie...
you are being absurd!
Why ascribe to an object
a vague and immeasurable force like vis viva?
It is a return to the old ways!
Are you capable of discovering something of your own?
I discovered you!
WOMAN: There is no right time for the truth.
Fraäulein Meitner?
Yes?
Otto Hahn.
The nucleus is our focus.
The Jewess endangers our institute.
We can't harbor a Jew!
If she stays, the regime will shut us all down!
They've split the atom.
No, no, no.
You've split the atom!
Energy equals mass times the square of the speed of light!
( laughs )
Would you like me to check your mathematics?
Captioning sponsored by EXXONMOBIL,
DAVID H. KOCH, HOWARD HUGHES MEDICAL INSTITUTE,
THE NATIONAL SCIENCE FOUNDATION,
THE ALFRED P. SLOAN FOUNDATION,
THE U.S. DEPARTMENT OF ENERGY,
AND THE UNIVERSITIES RESEARCH ASSOCIATION, INC.
Major funding for NOVA is provided NARRATOR: A hundred years ago,
a deceptively simple formula revealed a hidden unity
buried deep in the fabric of the universe.
It tells of a fantastic connection
between energy, matter and light.
Its author was a youthful Albert Einstein.
It's the most famous equation in the world:
E equals m c-squared.
MAN: All aboard!
( train whistle toots )
LITHGOW: But while we've all heard
of Einstein's big idea,
very few of us know what it means.
In fact, E equals m c-squared is so remarkable
that even Einstein wasn't sure if it was really true.
WOMAN: Albert, darling,
you're later than I expected.
We've only got sausage and cheese tonight.
What is it?
We need to talk.
Has something happened?
Oh, no, nothing.
Sorry, no.
I spent most of the day
staring out the window at work looking at trains,
and I started to think
about an object and how much energy it had.
Can I explain it to you?
Of course you can.
But first... ( kisses ) dinner!
Hmm?
Food, then talk.
I think the gods are laughing at me.
LITHGOW: The gods were not laughing at Einstein.
He'd united in one stunning insight
the work of many who had come before him--
scientists who'd fought and even died
to create each part of the equation.
The story of E equals m c-squared
starts long before Einstein
with the discovery of "E" for energy.
In the early 19th century,
scientists didn't think in terms of "energy";
they thought in terms of individual "powers" or "forces."
These were all disconnected, unrelated things:
the power of the wind, the force of a door closing,
a crack of lightning.
( thunder rumbles )
The idea that there might be
some sort of overarching, unifying energy
which lay behind all these forces had yet to be revealed.
One lowly man's drive
to understand the hidden mysteries of nature
would begin to change all that.
MAN: Young Michael Faraday hated his job.
He was uneducated, the son of a blacksmith.
He'd been lucky to become a bookbinder's apprentice.
But Faraday craved one thing.
He craved knowledge.
He read every book that passed through his hands.
He developed a passion for science.
All of his free time and his meager wages were poured
into his self-education.
He was on the threshold of an incredible journey
into the invisible world of energy.
LITHGOW: Faraday had impressed one of his master's customers
and was rewarded with a ticket that would change his life.
Excuse me, please.
Can I pass, please?
"Can I pass?"
Some of us are trying to improve ourselves,
if people will let us.
Of course, of course-- pass, pass.
This way to a better life.
( chuckles )
MAN: In the early 1800s, science was the pursuit of gentlemen,
something Faraday was clearly not.
He had a rudimentary education,
he'd read widely, he'd gone to public lectures,
but in 1812 he was given tickets to hear Sir Humphry Davy,
the most prominent chemist of the age.
( groans )
( laughing )
LITHGOW: Nineteenth-century scientists were the pop stars of their day.
Their lectures were hugely popular.
Tickets were hard to come by, and Davy reveled in his status.
They're waiting.
I know.
LITHGOW: He was also a keen follower of the latest fashion--
nitrous oxide, or laughing gas.
He said it had all the benefits of alcohol without the hangover.
( laughing )
( clears throat )
Electricity, ladies and gentlemen,
a mysterious force that can unravel the confusing mixture
of intermingled substances
that surround us and produce pure... pure elements!
GATES: Davy was an absolutely first-rate scientist.
However, many will come to say
that his greatest discovery is Michael Faraday.
DAVY: Metals-- unknown, that is,
until I isolated potassium from molten potash and sodium,
as I showed you last time, from common salt.
( voice fades ): That same magical electric...
LITHGOW: Faraday may not have been born a gentleman,
but he wasn't going to let class barriers stop him
from pursuing a career in science.
He worked for nights on end
to bind his lecture notes into a book for his new hero.
FARADAY: Lord, help me to think only of others...
to be of use to mankind.
Help me be part of the great circle
that is your work and love.
Lord, I am your servant.
This is excellent work, Faraday.
So, what is it you aim to do with your life?
My desire, sir, is to escape from trade,
which I find vicious and selfish,
and to become a servant of science,
which, I imagine, makes its pursuers amiable and liberal.
( laughs briefly )
Really?
Well, I shall leave it to the experience of a few years
to set you right on that score.
Look, I haven't anything at the moment.
I'll send a note if anything comes up.
LITHGOW: Despite this humiliating setback,
Faraday was determined to break free from his daily toil.
His patience was rewarded.
( explosion, then Davy screams )
DAVY: Newman...
meet Mr. Michael Faraday.
He's going to be my helper while I recover.
He assures me he is a Christian fellow.
Perhaps with God and Faraday in charge of the chemicals,
you and I will be safe in our place of work.
Thank you, Professor Davy.
Welcome, Faraday.
Oh, no, thank you,
and thank you, Sir Humphry.
Just stick to your job and do as you're told
and you'll be fine, Faraday.
LITHGOW: Faraday became the laboratory assistant, eagerly absorbing
every scrap of knowledge that Davy deigned to impart.
But in time, the pupil would surpass the master.
The big excitement of the day was electricity.
Another charge, Newman.
LITHGOW: The battery had just been invented,
and all manner of experiments were being done.
But no one really understood
what this strange force of electricity was.
GATES: The academic establishment at the time thought
that electricity was, you know,
like a fluid flowing through a pipe, pushing its way along.
But in 1821, a Danish researcher showed
that when you pass an electric current through a wire
and place a compass near it,
it deflected the needle at right angles.
LITHGOW: This was the first time
researchers had seen electricity affect a magnet,
the first glimpse of two forces
which had previously been seen as entirely separate
now unified in some inexplicable way.
Faraday, come look at this.
You're the bright spark around here.
Perhaps you can work it out.
Oersted's reported an amazing finding.
We're just replicating it here.
Let's try the compass on the other side.
MAN: Now, that is
remarkable.
But if the electrical force is flowing through the wire,
why does the needle
not move in the same direction,
parallel to the wire?
Quite.
Let's try turning the whole apparatus round.
Again, Newman.
So, the electrical force goes this way.
The compass points that way.
How can one affect the other?
( utters sound )
Perhaps the electricity is throwing out
some invisible force
as it moves along.
What?
Perhaps some sort of electrical force is emanating
outwards from the wire.
Oh, my dear boy, let me tell you
that at the University of Cambridge,
electricity flows through a wire,
not sideways to it.
That may be what they teach at Cambridge,
but it doesn't explain what's happening
before our eyes.
No, now, let's just get on.
Let's swap the compass to below the wire.
LITHGOW: Why the compass was deflected at right angles,
why the electricity was affecting the compass at all,
dumbfounded Davy and many others.
MINISTER: As we celebrate the marriage of Michael and Sarah...
LITHGOW: For Faraday, however, the problem became an obsession.
It was a fascination inspired by his religion.
For him, the problem was a way
to understand God's hidden mysteries.
BODANIS: There is a small, almost persecuted group in London
called the Sandemanians.
They were a religious... not really a sect,
they were just a small subset, sort of like Quakers.
Faraday was a member of that group.
It was a very gentle, decent group.
They believed that underneath the whole surface of reality,
everything was created by God in a unified way;
that if you opened up one little part of it,
you could see how everything was connected.
Michael Faraday was someone
who, like Einstein, thought in terms of pictures.
BODANIS: Faraday was different from anybody else.
He had a flair for understanding his experiments,
for understanding what was really going on inside them.
LITHGOW: By methodically placing a compass
all around an electrified wire,
Faraday started to notice a pattern.
What everyone else at the time had been taught
was that forces travel in straight lines.
Faraday was different.
Faraday imagined that invisible lines of force
flowed around an electric wire.
And then he imagined
that a magnet had similar lines emerging from it
and that those lines would get caught up in this flow.
It was a bit like a flag in a wind.
LITHGOW: But Faraday's great leap of imagination
was to turn this experiment on its head.
Instead of an electrified wire moving a compass needle,
he wondered if he could get a static magnet to move a wire.
I've never seen you like this, Faraday.
( chuckling ): You look like a happy child.
I'm shaking, Newman.
Underneath, I'm shaking.
( gasps )
You see, John?
You see?
Yes.
GATES: This is the experiment of the century.
It's the invention of the electric motor.
Scale up the magnets and the wires,
make them really big, attach heavy weights to them
and they'll be dragged along.
But almost more importantly,
he's inventing a new kind of physics here.
LITHGOW: Although he didn't realize it at the time,
Faraday had also just demonstrated
an overarching principle.
The chemicals in the battery
had been transformed into electricity in the wire,
which had combined with the magnet to produce motion.
Behind all these various forces there was a common energy.
BODANIS: A couple of months earlier,
Davy had been elected president of the Royal Society,
which was the elite body of English science.
But then he saw this great discovery
published in the Quarterly Journal of Science.
I don't know if he was envious,
but he certainly saw that this young man
who had been his assistant, this mere blacksmith's son,
had come up with one of the greatest discoveries
of the Victorian era.
Davy accuses Faraday of plagiarizing similar work
from another eminent British scientist, William Wollaston.
So, Faraday, what does Wollaston make of all this?
He's written to me and assures me
that he's taken no offense,
and he acknowledges that what I published
was entirely my own work.
Quite, quite.
Davy is just being an ass.
But will Davy now retract his allegation?
Sadly, no.
In fact, he is still vehemently opposed
to you being elected a member of the society.
Really.
And what do you think?
Faraday, my dear boy, you have my vote.
And mine.
And I believe you even have Wollaston's.
Oh... What a mess!
Well, no matter, no matter--
it's the science that counts.
So, tell me,
how does this wire of yours spin round its magnet?
What mysterious forces are at play?
There seems to be an electromagnetic interaction.
In my mind, I see a swirling array
of lines of force spinning
out of the electrified wire
like a spiraling web.
But invisible lines of force--
it's all a bit vague, isn't it?
Faraday, might I have a word in private?
Certainly.
Listen, Faraday,
let's stop this nonsense.
I want you to take down your ballot paper
from the notice board.
Sir Humphry, I see no reason to take it down.
My friends have proposed me.
It is they who put the paper up.
I will not take it down.
Good day.
LITHGOW: Faraday was elected to the Royal Society.
Davy died five years later,
a victim of his many gaseous inhalations.
In time, Faraday's world of invisible forces would lead
to a whole new understanding of energy.
He'd started what Einstein would call the "great revolution."
It was in the very heart of this exciting new world of energy
that Einstein grew up.
EINSTEIN: My father and uncle wanted to make their fortune
by bringing electric light to the streets of Germany.
From an early age, I loved to look at machines,
understand how things work.
He's going to kill himself.
Albert, stay there.
( man scolding in background )
EINSTEIN: I experienced a miracle when my father showed me a compass.
I trembled and grew cold.
There had to be something behind objects that lay deeply hidden.
At high school, they had their ideas about what I should learn.
I had my own.
Einstein!
EINSTEIN: I was merely interested in physics, maths, philosophy
and playing the violin.
Everything else was a bore.
Einstein!
On your feet!
As you obviously know everything
about geology, tell me,
how do the rock strata run here?
It's pretty much the same to me
whichever way they run, Herr Professor.
LITHGOW: Einstein's teachers tried to drum into him,
as Faraday had shown,
that energy could be converted from one form into another.
They also believed that all forms of energy
had already been discovered.
Einstein was going to prove them wrong.
He would discover a new, vast reservoir of energy,
hidden where no other scientist had ever thought of looking--
deep in the heart of matter.
A hundred years before Einstein's birth,
King Louis XV was on the throne of France.
But the ancient, absolute power of the monarchy over the people
was starting to be challenged.
MAN:Jacques,
leave the windows.
Forget the rain.
We need air.
LITHGOW: The French Revolution was just around the corner.
( thunder rumbles )
WOMAN: This was the era of enlightenment,
when intellectuals believed very firmly
that the way forward lay in science.
And they felt that one of the first tasks
that lay ahead of them was to rationalize
and to classify every single kind of matter
so they could see how it all interacted together.
LITHGOW: Antoine Lavoisier, a wealthy, aristocratic young man,
decided to take up this task,
to see if there was some basic connection
between all the stuff of everyday life:
all the different substances in the world.
But what worked for Lavoisier as a scientist--
his meticulous, even obsessive attention to detail--
was also to be his downfall.
Monsieur Lavoisier, you are, if my eyes do not deceive me,
consuming only milk this evening.
First you had a glass of milk,
now you are "eating" a bowl of milk.
Will you next move on to a plate of milk?
( chortles )
LAVOISIER: Your precise observations
commend you as a lady of scientific curiosity,
Mademoiselle.
Most unusual.
As you seek knowledge,
so I shall dispense it.
For the last five weeks, I have taken nothing but milk.
MAN: Good God, man,
I would rather die than fast
on milk for five weeks!
Are you in the grip of some horrendous ailment?
On the contrary.
I am investigating the effects
of diet on health.
MAN: Monsieur, with the greatest of respect
to a member of the Royal Academy of Sciences,
your gut must think your throat has been slit!
( laughs loudly )
( laughter spreads )
Whereas your gut, Count, is no doubt petitioning the Academy
for a widening of your throat.
WOMAN ( gasping ): Marie Anne!
How dare you
insult the count?
Don't forget what the count offers...
not just marriage, but think
of how you will be introduced
to all the salons.
You will be
the toast of Paris.
LAVOISIER: Would it not be a shame, Madame,
to burden you
with the duties of matrimony before you have had a chance
to experience your curiosity for nature?
Shall we all go through?
It's getting rather hot in here.
Do you really plan to marry d'Amerval?
There is a plan, but it is not mine.
Then I must contrive to save you.
LITHGOW: Lavoisier wasn't a scientist by profession.
He was the head of tax enforcement in Paris.
His great idea was to build a huge wall around the city
and to tax everything that came and went.
But his taxes on the simple things in life--
bread, wine and cheese--
did not endear him to the average Parisian.
This scrupulous, fastidious young man
did still allow himself the occasional act of passion.
In 1771, Lavoisier married Marie Anne Paulze,
the daughter of his colleague in the tax office.
Thus he saved her, as he had promised,
from an arranged marriage to a count 40 years her elder.
Allow me to show you something.
FARA: Lavoisier, I think, found his job as a tax collector
really rather tedious,
and the times he looked forward to were the evenings
and the weekends, when he could indulge his passion
for chemical experimentation.
And he called those times his jours de bonheur,
his "days of happiness."
Madame.
What will happen if I take a bar of copper or iron
and leave it outside
in the rain for months on end,
Madame Lavoisier?
Mmm...
( giggles ): Monsieur Lavoisier?
The metals--
what will become of them?
Is this a verbal examination
prior to an examination proper, sir?
I merely seek the truth.
Then you toy with me, monsieur,
for you know the truth.
The copper will become covered in a green verdigris,
and the iron will rust.
I believe the term is
"calcined."
Most impressive, my charming wife.
But let me press you further.
Hmm?
When the metal rusts, does it get heavier
or lighter?
Why, sir, I think you mean to trap me.
Oh.
Then perhaps this little butterfly should land
and allow me to take a closer look.
Every last citizen in France of sensible age knows
that when a metal rusts, it wastes away,
it gets lighter and eventually disappears.
Ah, but...
Ah, stop.
I have not finished.
Contain yourself, sir.
There is more.
In a recently published pamphlet
by a brilliant young chemist,
Antoine Lavoisier demonstrates
that the iron combines with the air.
It, in fact, becomes heavier.
Most impressive.
I intend...
Now, whatever you intend, monsieur,
I intend to be by your side.
I will learn all I can about your science
and become your worthy colleague.
Then let me show you how the iron combines with the air
to form such a delicate union.
Tomorrow, monsieur.
Tomorrow.
LITHGOW: Marie Anne learned chemistry at her husband's side,
but soon sought other ways to contribute to his work.
She learned English
so that she could translate contemporary scientific works.
She took drawing lessons
so that she could record in forensic detail
the minutiae of their work together.
She ran their laboratory
and was the public face of Lavoisier, Inc.
She was central to the whole research effort.
Monsieur,
that is a terrible thing to say.
( giggles )
You are a cheeky man.
( both laugh )
LAVOISIER: This way, please, gentlemen.
Messieurs...
it is my great ambition
to demonstrate that nature is a closed system,
that in any transformation,
no amount of matter, no mass is ever lost
and none is gained.
Over here, please.
This precise amount of water is heated to steam.
This steam is brought into contact
with a red-hot iron barrel imbedded in the coals.
From this end we cool the steam
but, interestingly, we collect less water than we started with.
So clearly we lose a certain amount of water.
However, we also collect a gas,
and the weight of the iron barrel increases.
Now, when we combine these two increases--
the new weight of the iron barrel
and the gas we have collected--
they are exactly equal to the weight of the lost water.
Ah, but is it
atmospheric air, Monsieur Lavoisier?
No.
No, because I am measuring it to the very last grain,
I can see that it is lighter than the air around us
and, moreover...
it is flammable.
( whoosh and pop )
VoilĂ .
BODANIS: Water is made out of hydrogen and oxygen.
So what he had done is get the oxygen to stick
to the inside of a red-hot iron rifle barrel.
He was basically just making rust, which is oxygen and iron,
but he was making the rust really quickly.
Now, that left the hydrogen, what he called combustible air,
and that was just floating around as a gas.
( whoosh and pop )
No mass had been lost.
It had merely been transformed,
and now he wanted to transform it all back into water.
This is only the beginning.
In the next few months I hope to demonstrate
that I can recombine this combustible air with vital air
and transform them both back into water.
I will re-create exactly the same amount of water
that was lost here in this process.
It is my hope to complete the cycle--
water into gas into water...
and not a drop lost.
For a long time, Lavoisier had suspected
that the exact amount of matter, the mass
involved in any transformation was always conserved.
But to prove this,
he had to perform thousands of experiments,
and he had to do the measurements
with incredible accuracy.
That's where his great wealth
from being a tax collector came in.
He could afford to commission
the most sensitive instruments ever built.
He became obsessed with accuracy.
LITHGOW: But Lavoisier's exacting methods were also starting to anger
the growing mob of hungry, disenchanted Parisians.
( people yelling )
MARIE ANNE: Antoine.
Antoine.
Oh, wake up, Antoine.
I'm sorry.
What time is it?
It is almost time to receive Monsieur Marat.
The Academy asked you
to assess his designs.
He claims to have made a great discovery.
Oh, Antoine, have you forgotten?
Oh, God.
Another charlatan with an idea to peddle.
God, give me patience.
( Lavoisier coughs )
Ah, Monsieur Marat.
Monsieur.
I have invented a device
which projects an image
of the substance of fire onto a screen.
You see,
when a lantern is shone through a flame,
we see a shimmering pattern above the flame.
My device renders
the substance of fire visible.
Have you collected it, this substance of fire?
Have you trapped it and measured it?
Well, no, but...
but one can see it.
I'm sorry.
In the absence of exact measurements,
of precise observations,
without rigorous reasoning,
one can only be engaging in conjecture,
so this is not science.
I am not given
to conjecture, monsieur.
No, no.
If you will you excuse me.
I am extremely busy today.
Thank you.
Thank you.
So that is all?
Then good day, monsieur!
( slams on table )
Let me guess, Marat.
The king's scientific despot has decreed
that your invention does not conform
to the version of the truth
as laid down by the Academy.
Lavoisier.
He talks about facts, he worships the truth.
Listen to me, my friend.
They are all the same, the Royal Academies--
they insult the liberty of the mind.
They think they are the sole arbiters of genius.
They are rotten to the core--
just like every other tentacle of the king.
The people-- it is they who will determine right and wrong.
Don't worry.
In my next pamphlet I will expose this persecutor of yours.
LITHGOW: For years, the Lavoisiers burned, chopped, melted
and boiled every conceivable substance.
They'd shown that as long as one is scrupulous
about collecting all the vapors, liquids and powders
created in a transformation, then mass is not decreased.
Liquids might become gases, metals may rust,
wood may become ash and smoke,
but matter, the tiny atoms that make up all substances,
none of it is ever lost.
The crowning glory of this opus was
their remarkable use of static electricity
to cause oxygen and hydrogen to recombine back into water.
What is happening?
( explosions in distance )
LITHGOW: As the French Revolution exploded,
the royal family and whole swaths of aristocrats
lost their heads on the guillotine.
FARA: To the French revolutionaries of 1790,
Lavoisier meant one thing and one thing only:
he was the despised tax collector
who'd built that wall around Paris.
LITHGOW: Lavoisier's job as a tax collector
brought him under suspicion.
He was denounced
by a failed scientist turned radical journalist,
Jean Paul Marat.
( pounding at door )
( pounding at door )
( knocking at door )
OuĂą est Lavoisier?
Je ne sais pas.
Lavoisier!
Lavoisier!
Lavoisier!
( sobbing )
( crowd yelling )
( crowd cheering )
BODANIS: What Lavoisier did
was absolutely central to science
and especially to E equals m c-squared.
Because what he said is, if you take a bunch of matter,
you can break it apart, you can recombine it,
you can do anything to it
and the stuff of the matter won't go away.
If the mob burned Paris to the ground, utterly razed it,
shattered the bricks into rubble and dust
and burned the buildings into ashes and smoke,
it turns out if you put a huge dome over Paris
and weighed all the smoke and all the ashes
and all the rubble,
it would add up to the exact same weight as the original city
and the air around it before.
Nothing disappears.
LITHGOW: A century later, all of nature had been classified
into two great domains.
There was energy-- the forces that animated objects;
and there was mass--
the physical stuff that made up those objects.
The whole of 19th-century science rested
on these two mighty pillars.
The laws that governed one did not apply to the other.
But young, newly enrolled physics student Albert Einstein
didn't like laws.
Good grief, Einstein.
What happened to you?
It is more than a little ironic,
having been reprimanded yesterday
by that idiot Professor Pernet for poor attendance,
that I should in fact attend a practical lesson
which was as long as it was boring,
and utterly pointless, by the way,
only to be the victim of an explosion
of my own apparatus.
It was your own fault, then?
Thank you.
And how are you today, Fraulein Maric?
Extremely well, Herr Einstein.
All the better for seeing
you have escaped the physics laboratory with your life.
Well, in order not to alarm you any further, I pledge
to forever continue my studies here at the Cafe Bahnhof,
reading only the great masters of theoretical physics
and eschewing the babbling nonsense of the polytechnicians.
( chuckles )
That's about all you ever do.
It's getting a little stuffy in here, Fraulein Maric.
Would you care to take a walk with me?
There's something I'd like to discuss with you.
Why, Herr Einstein...
of course.
Perhaps you'd like me to tell you
what you have missed in lectures this week?
MAN: Einstein wasn't exactly a model student.
He excelled in certain subjects, especially physics and math,
but he wasn't very diligent in a lot of his other classes.
He was undoubtedly very questioning,
which seems to have annoyed most of his professors
throughout his life.
He would pursue his fascinations
with just incredible determination.
MAN: We know from his letters
that Einstein, even from the age of 16,
was literally obsessed with the nature of light.
Everyone he could speak to-- his friends, his colleagues,
even his then girlfriend, Mileva Maric,
who would become his wife--
everyone he badgered with the question: what is light?
( laughing )
What would I see if I rode on a beam of light?
What?
A beam of light?
By what method do you propose to ride on this beam of light?
The method is not important.
Let us just imagine we two are
( loudly ): young...
Shh!
( loudly still ): radical, bohemian experimenters,
hand-in-hand, on a journey to the outer reaches of the universe,
and we are riding on the front of a wave of light.
( laughs )
I really don't know
what you are suggesting, Herr Einstein.
Do you wish to hold my hand or ridicule me?
Ridicule you?
No, never.
I merely want you to help me to understand.
What would we see, do you think...
Um...
if we were together and we sped up... and up
until we caught up to the front of a beam of light?
LITHGOW: It was Einstein's relentless pursuit of light
which would bring about a revolution in science.
With light he would reinvent the universe
and find a hidden pathway
that would unite energy and mass.
Light moves incredibly fast, 670 million miles per hour.
That's why scientists use the term "c".
It stands for celeritas-- Latin for "swiftness."
Long before the 19th century,
scientists had computed the speed of light,
but no one knew what light actually was.
Back in England, a man we've already met was willing to make
an educated guess.
After Sir Humphry Davy's death,
Michael Faraday became Professor Faraday,
one of the most important experimenters in the world.
The scientific establishment still found it hard to accept
that electricity and magnetism were just two aspects
of the same phenomenon,
which Faraday called "electromagnetism."
But now he has
an even more outrageous proposal for his audience.
Invisible lines that can emanate
from electricity in a wire,
from a magnet or... even from the sun.
( crowd laughs )
For it is my contention
that light itself is just one form of these vibrating lines
of electromagnetism.
( laughter )
LITHGOW: For 15 years, Faraday struggled to convince the skeptics
that light was an electromagnetic wave,
but he lacked the advanced mathematics to back up his idea.
Eventually, someone came to his rescue.
Professor James Clerk Maxwell believed
in Faraday's far-sighted vision,
and he had the mathematical skill to prove it.
Maxwell and the aging Faraday became close friends.
James.
James, forgive me.
( gasps )
A word of advice: don't get old.
( chuckles )
Michael, how are you?
Oh, I'm fine.
Memory isn't too good, but...
Well, I thought you might like to see
what I've just published.
Oh, yes, yes.
Splendid.
So your results show that when electricity flows along a wire,
what it actually does is create a little bit of magnetism.
Now, as that magnetic charge moves,
it creates a little piece of electricity.
Electricity.
Electricity and magnetism are interwoven,
like a... a never-ending braid.
So it is always pulsing forward.
That's wonderful.
Wonderful.
Michael.
Michael, there's something very crucial in maths.
This electricity producing magnetism
and magnetism producing electricity--
it can only ever happen at a very particular speed.
The equations are very clear about it.
They come up with just one number:
670 million miles per hour.
I'm not sure I...?
That's the speed of light.
That is the speed of light!
Well, that means you were right all along.
Light is an electromagnetic wave.
LITHGOW: Maxwell had proven Faraday right.
Electricity and magnetism are just two aspects
of a deeper unity, a force now called electromagnetism,
which travels at 670 million miles per hour.
In its visible form, it is nothing other than light itself.
And nothing fascinated the young Einstein more than light.
( playing light romantic piece )
( sighs )
We have lectures in half an hour.
Oh, let me think.
Professor Weber and his life-draining monologue
or you... ( kisses )
Mozart and James Clerk Maxwell?
We can't.
We'll get a warning.
Our project is too precious
to waste time listening to those dullards.
Come with me,
we'll read Maxwell
and think about the electromagnetic theory of light!
( giggling )
Oh, why, my dear little Johnnie,
how you enchant a lady.
MARIC: She's very pretty.
Yes, but can she soar and dance like our dark souls do?
( sighs )
BODANIS: Maxwell's equations contained an incredible prediction.
They said you could never catch up to a beam of light.
Even if you were traveling at 670 million miles an hour,
you would still see light squiggle away from you
at 670 million miles an hour.
Do you see how she stares at that wave?
Yes.
You see how for her it is static?
Yes.
She and the wave are traveling at the same speed.
We see the wave moving through the water.
But relative to her, it just sits there.
So is light like that?
Common sense would say that if you caught up to a light beam,
there would be a wave of light just sitting there.
Maybe it would be shimmering,
a bit of electricity and a bit of magnetism.
So if she was traveling alongside the light wave,
it wouldn't be moving.
It would be static.
But Maxwell says you can't have static light.
Maybe Maxwell is wrong.
Maybe if you catch up to light,
it is static, Albert, like a wave next to a boat.
Imagine if I were sitting still and holding a mirror to my face.
The light travels from my face to the mirror and I see my face.
Yes.
However, if I and the mirror
were traveling at the speed of light?
You're going at the same speed as the light leaving your face?
Exactly.
The light never reaches the mirror?
So would I be invisible?
Hmm.
That doesn't make sense.
LITHGOW: Young Einstein was starting to realize
that light was unlike any other kind of wave.
Einstein was about to enter a surreal universe
where energy, mass and the speed of light intermingled
in a way no one had ever suspected.
But there was one last mathematical ingredient
that Einstein would need:
the everyday process of squaring.
Long before the French Revolution,
scientists were not sure how to quantify motion.
Challenge.
LITHGOW: Equations that explained
how objects moved and collided were in their infancy.
( growls )
( kisses and giggles )
LITHGOW: A crucial contribution to this subject
would come from an unusual source.
Meet the aristocratic 16-year-old daughter
of one of King Louis XIV's courtiers, EÉmilie du Châtelet.
( both grunting )
( groaning ) ( giggling )
Quickly, Father is coming!
LITHGOW: EÉmilie du Châtelet would have a huge effect on physics
in her tragically short lifetime.
Unheard of for a woman of her time,
she would publish many scientific works,
including a translation of Sir Isaac Newton's Principia,
the greatest treatise on motion ever written.
Du Châtelet's translation is still
the standard text in France today.
Musa, mihi causas memora...
Muse, my memory causes...
O Muse!
The causes and the crimes relate
What goddess was provoked, and whence her hate
For what offence the Queen of Heaven began
To persecute so brave, so just a man!
Do not be cross with your sister,
because she persecutes many a just man!
Only the other night,
EÉmilie silenced the duc du Luynes
when she divided a ridiculously long number in her head
in a matter of seconds.
You should have seen the incredulity on their faces
when they realized EÉmilie was correct.
Was it my sister's astounding intelligence
or her boundless beauty
that made their mouths gape, I wonder?
Ah well, yes, you have a point, monsieur.
Messieurs, I thank you for your kindness.
I fear, however, that my wit is only a curiosity to others.
If only my mind were permitted opportunity.
My dearest EÉmilie.
You are blessed with intellect and courage.
Use them both and the world will fall at your feet.
No...
WOMAN: In one sense,
she is a woman utterly out of her true time and place.
She's a philosopher, a scientist,
a mathematician, a linguist.
She demands a freedom
that women didn't begin to enjoy until over 150 years later--
a freedom to study science,
to write about it, and to be published.
LITHGOW: Du Châtelet married a general in the French army at age 19
and had three children.
She ran a busy household,
all the while pursuing her passion for science.
She was 23 when she discovered advanced mathematics.
She enthusiastically took lessons
from one of the greatest mathematicians of the day,
Pierre de Maupertuis.
He was an expert on Newton,
and she was his eager young student;
it seems they had a brief affair.
But then he set off on a polar expedition.
Du Châtelet then fell passionately in love
with Voltaire, France's greatest poet.
A fierce critic of the king and the Catholic Church,
Voltaire had been in prison twice
and exiled to England,
where he became enthralled by the ideas of Newton.
Back in France,
it wasn't long before he again insulted the king.
Du Châtelet hid him in her country home.
The poor little creature is devoted to him.
LITHGOW: Isolated far from Paris, du Châtelet and Voltaire
turned her chateau into a palace of learning and culture,
complete with its own tiny theater,
and all with the apparent blessing of her husband.
FARA: There's a great deal of myth surrounding du Châtelet
and her love life
and most of it is very exaggerated.
But her husband did accept Voltaire into his household,
and he often went to Paris on behalf of Voltaire;
he went to his publisher to plead Voltaire's case
to keep Voltaire out of jail.
And it is also true that EÉmilie du Châtelet
did have several affairs of a fleeting nature.
( audience applauding )
Bravo!
Bravo!
ZINSSER: She created an institution to rival that
of France's Royal Academies of Sciences.
Many of the great philosophers, poets
and scientists of the day visited.
Ah, monsieur... you are young.
I hope that soon you will judge me
for my own merits, or lack of them,
but do not look upon me
as an appendage to this great general
or that renowned scholar.
I am in my own right
a whole person,
responsible to myself alone
for all that I am,
all that I say...
( blows )
all that I do.
LITHGOW: Du Châtelet learned from the brilliant men around her,
but she quickly developed ideas of her own.
Much to the horror of her mentors,
she even dared to suspect that there was a flaw
in the great Sir Isaac Newton's thinking.
Newton stated that the energy of an object,
the force with which it collided with another object,
could very simply be accounted for
by its mass times its velocity.
In correspondence with scientists in Germany,
du Châtelet learned of another view,
that of Gottfried Leibniz.
He proposed that moving objects had a kind of inner spirit.
He called it Vis Viva, Latin for "living force."
Many discounted his ideas, but Leibniz was convinced
that the energy of an object was made up
of its mass times its velocity squared.
Taking the square of something is an ancient procedure.
If you say a garden is four square,
you mean that it might be built up
by four slabs along one edge and four along the other.
So the total number of paving slabs is
four times four: 16.
If the garden is eight square-- eight by eight--
well, eight squared is 64.
It'll have 64 slabs in it.
This huge multiplication, this building up by squares,
is something you find in nature all the time.
EÉmilie?
EÉmilie, you are being absurd!
Why ascribe to an object
a vague and immeasurable force like Vis Viva?
It is a return to the old ways!
It is the occult!
When movement commences,
you say it is true that a force is produced
which did not exist until now.
Think of our bodies-- to have free will
we must be free to initiate motion.
So all Leibniz is asking is,
where does all this force come from?
In your case, my dear,
the force, I am sure, is primeval.
Oh!
You're infuriating!
You hide behind wit and sarcasm.
You only think you understand Newton.
You are incapable of understanding Leibniz.
You are a provocateur.
Everything you do is about something else
and makes trouble for you.
Criticize this, denounce that.
Are you capable of discovering something of your own?
I discovered you!
LITHGOW: Despite the overwhelming support for Newton,
du Châtelet did not waver in her belief.
Eventually, she came across an experiment
performed by a Dutch scientist, Willem 's Gravesande,
that would prove her point.
'S Gravesande in Leiden has been dropping lead balls
into a pan of clay.
( sarcastically ): Dropping lead balls into clay!
How very imaginative.
DU CHATELET: Using Newton's formulas, Monsieur Voltaire,
he then drops a second ball from a higher height,
calculated to exactly double the speed
of the first ball on impact.
So, messieurs, care for a little wager?
Newton tells us that by doubling the speed of the ball,
we will double the distance it travels
into the clay.
Leibniz asks us to square that speed.
If he is correct, the ball will travel not two,
but four times as far.
So who is correct?
Messieurs,
I feel Mr. Newton's reputation dwindling
ever so slightly.
Oh, Maupertuis!
Do not succumb to her!
There is no earthly reason
to ascribe hidden forces
to this Dutchman's lead balls!
( men laughing )
Well...
the ball travels four times further.
Turns out Leibniz is the one who is right--
it's the best way to express the energy of a moving object.
If you drive a car at 20 miles an hour,
it takes a certain distance to stop if you slam on the brakes.
If you're going three times as fast--
you're going 60 miles an hour--
it won't take you three times as long to stop,
it'll take you nine times as long to stop.
Oh.
Well... it does seem
worth consideration.
Perhaps we might look over his calculations?
I have already checked his figures.
I am sure Leibniz is correct on this point.
I intend to include
a section on this matter in my book.
MAUPERTUIS: Really?
Do be careful, madame.
Do you think the Academy is ready for such an opinion?
Quite, quite.
We really should be careful.
"We"?
I see no reason to delay.
There is no right time for the truth.
ZINSSER: EÉmilie du Châtelet published
her Institutions of Physics in 1740,
and it provoked great controversy.
Voltaire wrote
that "She was a great man whose only fault was being a woman."
In her day, that was a great compliment.
I am with child.
You are sure?
Undoubtedly.
Two to three months.
I'm afraid that...
You are afraid?
You should have...
Well, this child is obviously not mine.
Nor is it your husband's.
( sighs )
Oh, EÉmilie.
EÉmilie.
EÉmilie du Châtelet knew that in the 18th century
for a woman to become pregnant at the age of 43
was really very dangerous,
and all the while she was pregnant
she had terrible premonitions about what was going to happen.
LITHGOW: All her life, du Châtelet had tried to rise above
the limitations placed on her gender.
In the end, it was an affair with a young soldier
that led to her demise.
Six days after giving birth to her fourth child,
she suffered an embolism and died.
EÉmilie du Châtelet's conviction
that the energy of an object
is a function of the square of its speed
sparked a fierce debate.
After her death,
it took a hundred years for the idea to be accepted--
just in time for Einstein to use this brilliant insight
to finally bring energy and mass together with light.
Einstein pursued light right through university and beyond.
Unfortunately, he'd upset so many professors
that no one would write him a reference.
He accepted a low-paying job in the Swiss patent office.
He and Mileva married and had a child.
The young family struggled.
But none of it seems to bother Albert.
Einstein?
I see you are busy,
as usual.
Look, Einstein...
Albert.
You have shown some quite good achievements.
But, listen...
About your promotion.
I really think it would be better to wait
until you have become more fully familiar
with mechanical engineering.
I'm sorry.
Perhaps next time, hmm?
MILEVA: But I wanted to hire a maid
so I can get back and finish my degree.
Now I will never pass my dissertation.
Oh, come, come, my pretty little duck.
All will be fine, you'll see.
But how will it be fine, Albert?!
Do I have to just wait another year
until you are promoted?
( baby crying )
Come on.
Come on, my little one.
Oh, there we are.
( baby continues crying )
All will be fine.
All will be fine, you'll see.
There really is a very charming,
but kind of a self-centered streak to Einstein.
He focuses only on his particular obsessions.
If the rest of the world fits in around him, that's fine,
if they can't, it doesn't bother him.
( no voice )
Albert, Albert, Albert.
A pretty neck and your head spins.
Besso, we must behold and comprehend the mysterious.
Well, that kind of mysterious is going to get you into trouble.
I'll tell you what is truly mysterious:
the secret of a long and happy marriage.
The mathematics are fine, if a little unconventional,
but this only works for big systems.
It'll fall down when you apply it to small systems.
I disagree.
BESSO: Oh, no.
Here we go--
another grand theory by Herr Albert Einstein,
Patent Clerk,
Third Class.
What would happen if one applied those formulae
to electromagnetic radiation?
Albert,
you can't just take one bit of physics and apply it
without proper regard to a completely different area.
Why not?
Albert.
I know you like the grand linkages,
the big theories,
but wouldn't things be better all round
if you just got going in some small area?
Got a university post.
Get a decent wage, for God's sake.
At least Mileva could study again.
Then she'd be happy, and you'd be happy.
Ah, the vulgar struggle for survival: food and sex.
Spoken like a true bourgeois.
Besso, I want to know how God created this world.
I am not interested in this or that phenomenon,
in the spectrum of this or that element.
I want to know His thoughts.
The rest... they're details.
Yes, but you can't feed your children
on His thoughts, Bertie.
KAISER: So it turns out, Einstein was going for a walk
with his very close friend, Michele Besso.
They'd studied physics together
and talked about physics and philosophy for years and years.
They were very close.
They had cornered the question of light
from every possible angle.
See these clocks are over here?
LITHGOW: As Einstein and Besso were ruminating
on how much time it would take light to reach them
from clocks at different distances,
Einstein had a monumental insight.
( church bell tolling )
( exhales deeply )
Thank you.
Thank you.
I have completely solved the problem.
Albert!
BODANIS: What Einstein did was completely turn the problem on its head.
Other scientists had found it impossible
to accept Maxwell's idea--
that light would always move away from you
at 670 million miles an hour,
even if you, too, were traveling really fast.
But Einstein just accepted that as a fact:
light's speed never ever changes.
Then what he did was bend
everything we know about the universe
to fit light's fixed speed.
What he discovered was that to do that
you have to slow down time.
His extraordinary insight is that time...
as you approach the speed of light,
time itself will slow down.
It's a monumental shift in how we see the world.
The instant, the very instant
when Einstein had this brilliant insight
that time could slow down,
well, the floodgates began to open.
( clocks ticking )
You see, before then people had assumed
that time was like a wristwatch on God's hand,
that it beat at a steady rate throughout the universe,
no matter were you were.
( clock's ticking slowing )
Einstein said no--
that the "tick, tick, tick" of this wristwatch
was actually the "click, click, click"
of electricity turning into magnetism
turning into electricity.
In other words, the steady pace of light itself.
BODANIS: 1905 was a miraculous year for Einstein and for physics.
He had an unbelievable outpouring of creativity.
It starts with his publication of a paper
on how to work out the true size of atoms.
Two months later
is the publication of his paper on the nature of light--
that's what will earn him the Nobel Prize.
The third paper, only a month later,
is on how molecules move when heated,
and that finally ends the debate on whether atoms really exist.
The fourth paper is published
at the end of this half-year period.
In it Einstein sets out
his theory of light, time and space.
It was the Theory of Special Relativity.
That changed the way we see the world.
LITHGOW: In Einstein's new world,
the one true constant was not time or even space, but light.
( steam whistle blowing, train chugging )
But Einstein's miracle year was not over.
( steam hissing, fire roaring )
In one last great 1905 paper,
he would propose an even deeper unity.
( steam whistle blowing )
As he computed
all the implications of his new theory,
he noticed another strange connection,
this one between energy, mass and light.
( train whistle blowing )
Einstein realizes that the speed of light
is kind of like a cosmic speed limit.
Nothing can go faster.
So imagine we have a train charging along,
and let's say it's getting up to the speed of light
and we're stuffing more and more energy in,
trying to get it to go faster and faster.
But it's still bumping up against the speed of light.
So all this energy, where does it go?
It has to go somewhere.
Amazingly, it goes into the object's mass.
From our point of view, the train actually gets heavier;
the energy becomes mass.
It's an incredible idea.
Even Einstein is amazed by it.
I think I have found a connection
between energy and mass.
If I am right, then energy and mass are not absolute.
They are not distinct--
they can be converted into one another.
Energy can become mass, and mass can become energy.
And not just energy equaling mass.
Energy equals mass times the square of the speed of light.
( cackles; laughs softly )
Would you like me to check your mathematics?
LITHGOW: Einstein sent his fifth great 1905 paper for publication.
In three pages he simply stated that energy and mass
were connected by the square of the speed of light--
E equals m c-squared.
With four familiar notes in the scale of nature,
this patent officer had composed a totally fresh melody--
the culmination of his ten-year journey into light.
Here we are for thousands of years
thinking that over here is a world of objects, of matter,
and over there is an entirely separate world
of movement, of forces, of energy.
And Einstein says, "No, they are not separate."
Energy can become mass,
and crucially, mass can also become energy.
There is a deep unity between energy, matter and light.
KAKU: E equals m c-squared.
That equation shows that every piece of matter in our universe
has stored within it a fantastic amount of energy.
The speed of light, for example,
is about 300 million meters per second.
You multiply that by itself and you get 90 quadrillion.
So in other words, what is matter?
In some sense, matter is nothing but the condensation
of vast amounts of energy.
So in other words, if you could unlock...
somehow unlock all the energy stored within my pen,
that would erupt with a force comparable to an atomic bomb.
After Einstein's fifth great 1905 paper,
physicists no longer spoke of mass or energy--
they are now the same thing to us.
( steam hissing )
LITHGOW: Probably the most miraculous year in science ends in silence.
The articles are published to resounding... nothing.
EINSTEIN ( voice echoing ): I think the Gods
are laughing at me.
LITHGOW: Then slowly it starts.
A letter here, a letter there.
For four years Einstein answered each inquiry dutifully,
trying to explain his difficult, complex ideas
to a confused physics community.
GATES: I love the idea that life just went on as normal.
Here are these universe-changing papers circling around,
and the world is... struggling to come to terms with them.
KAKU: Einstein had a fan club
of just one.
Luckily it happened to be the most important living physicist.
SUPERVISOR: Einstein.
Einstein.
Max Planck has sent someone to see you.
Max Planck?
Yes.
He has sent his assistant.
He's here to see you.
LITHGOW: Max Planck encourages the world's most eminent physicists
to take Einstein seriously.
After four years of waiting,
he is appointed professor of physics at Zurich University.
From there his career is meteoric.
He is made professor of physics in Berlin,
achieves world renown and becomes a household name.
He is the undisputed father of modern physics.
But Einstein's success was the downfall of his marriage.
In 1919 he divorced Mileva and married his cousin.
His fame led to numerous affairs.
E equals m c-squared became the Holy Grail of science.
It held out the promise of vast reserves of energy
locked deep inside the atom.
Einstein suspected
that it would take a hundred years of research to unlock it.
But he hadn't banked on the Second World War
and the genius of a Jewish woman in Hitler's Germany.
28-year-old Austrian Lise Meitner was painfully shy.
Despite her anxiety,
the young doctor of physics arrived in Berlin
determined to pursue a career
in the exciting new field of radioactivity.
Unfortunately, in 1907,
German universities did not employ female graduates.
Luckily, one man came to her aid.
Fraulein Meitner?
Yes?
Otto Hahn.
I'm a researcher in the Chemistry Institute.
Professor Planck suggested I...
Herr Hahn, I have read your papers on thorium and on mesothorium,
and Dr. Planck suggested that I...
Yes, he suggested that I speak with you.
I need someone to collaborate...
I think I could really help with the physical analysis.
And the mathematics?
Yes, yes-- and the mathematics.
Studying radioactive atoms
has become so much a collaboration
between chemistry and physics these days.
Yes, yes.
I'll ask Fischer for a laboratory, then.
Excellent.
I'll speak to you soon.
LITHGOW: Lise Meitner had just taken the first step on a journey
that would irrevocably change world history.
For her it would be a road marked with success and renown,
but also with terror and betrayal.
BODANIS: At this time, not a lot was known about the atom.
At first, people thought
it was like a miniature solar system;
there's a solid nucleus of the center
and electrons would spin around it,
sort of like planets around our sun.
A little later, some researchers proposed
that the nucleus itself wasn't a solid chunk
but was made up of separate particles,
of protons and neutrons.
But then-- in what are called radioactive metals,
things like radium and uranium--
the nucleus itself seemed to be unstable,
leaking out energy and particles.
Perhaps this was an example of E equals m c-squared--
the mass of a nucleus turning into energy.
LITHGOW: Meitner and Hahn's collaboration
to unlock the secrets of the atom started out
on an extremely unequal footing.
He was given a laboratory.
She was forced to work in a wood shop.
I see you haven't set your hair on fire.
Herr Hahn?
The boss-- he thinks that if he lets women
into the Chemistry Institute
they'll set their hair on fire.
Oh... so his beard must be fireproof.
( footsteps approaching )
Good day, Herr Hahn.
Good day.
You see?
I am nonexistent
to this place.
At least physicists recognize me for my abilities.
Yes, where would we chemists be
without the steadying hand of the physicist?
WOMAN: It took years, but Lise lost her shyness eventually.
In 1912, she and Hahn moved
to the brand-new Kaiser Wilhelm Institute for Chemistry,
where their status was really that of equals.
Lise became the first woman in Germany ever
to have the title of professor.
Lise...
I have news.
Oh?
You remember the art student
I told you of?
Yes, Edith.
Yes, well, I have, um...
asked her to marry me, and she has accepted.
Oh...
Oh, Dr. Hahn, congratulations.
Yes, well...
I wanted you to be the first to know.
I'm very pleased for you.
Very pleased.
SIME: Lise Meitner was warm-hearted by nature.
She had many friends
and she may have wanted to have a closer relationship with Otto.
But it really does seem that physics was Lise's first love--
maybe even her passion.
LITHGOW: The 1920s and '30s were the golden age of nuclear research.
The largest known nucleus at the time
was that of the uranium atom,
containing 238 protons and neutrons.
Meitner and Hahn were leading the race
to see if even bigger nuclei could be created
by adding more neutrons.
So... the atom, pretty familiar:
Nucleus in the center, electrons... orbiting around.
The nucleus is our focus.
The nucleus, made up of protons... and neutrons.
Now, the largest nucleus that we know
is that of the uranium atom.
Its nucleus is a tightly packed structure
of 238 protons and neutrons.
The thrust of our work is to try to fire neutrons
into this huge structure,
and if we can get a neutron to stick in here,
that will be a breakthrough.
LITHGOW: Meitner may have been on the brink of a major discovery,
but Germany in the 1930s was a dangerous place to be,
even for a world-class scientist.
The Jewess endangers our institute.
When the Nazis came to power, one of the first things they did
was to drive out Jewish academics from the universities.
Einstein was very prominent
and for that reason he was one of the first to go.
He was hounded out of Germany in 1933.
Lise was not dismissed at that time.
She was able to stay because she was Austrian.
But in March 1938, Austria was annexed into Germany
and at that point her situation became untenable.
( inaudible )
What is it?
Frightening news.
What's happened?
Kurt Hess is going around saying that I should be got rid of.
I, um...
I actually knew.
I heard today.
I was going to speak
to the treasurer of the institute
before I told you.
We're speaking tomorrow.
Come on, let's get you home.
It's late.
We'll finish up.
LITHGOW: The pressure on Meitner was unbearable.
Hahn, who was known for his anti-Nazi views,
did his best to protect her, at least initially.
I need to talk to you about Lise.
Not now, I'm too busy.
We have to protect her.
( sighs )
How?
What can we do?
The situation is the way it is.
Who knows what will happen next?
She can't stay; it's just not tenable.
But she hasn't got a visa or even a valid passport.
And she may soon be forbidden to leave Germany.
We can't harbor a Jew.
If she stays, the regime will shut us all down!
Lise...
Horlein demands that you leave.
You can't throw her out.
Horlein says you should not come
into the institute anymore.
Well, I have to write up
the thorium irradiation tomorrow,
so I have to come in.
You've given up.
LITHGOW: When it became clear that Meitner would be dismissed
and probably arrested,
physicists all around Europe wrote letters
inviting her to conferences,
giving her an excuse to leave Germany.
The Nazis refused to let her go.
In July of 1938,
a Dutch colleague traveled to Berlin
and illegally took Lise back with him
on a train to Holland.
The trip was so frightening
that at one point she begged to go back.
Despite the great danger, she got through.
SIME: She had lost everything-- her home, her position,
her books, her salary, her pension,
even her native language.
She had been cut off from her work just at the time
when she was leading the field
and was on the brink of a major scientific discovery.
LITHGOW: No matter what privations she suffered,
Lise was still thinking of physics.
Amazingly, she and Hahn were able to collaborate by letter.
MEITNER ( composing ): I hope, my dear Otto, that after 30 years
of work together and friendship in the institute,
that at least the possibility remains
that you tell me as much as you can
about what is happening back there.
SIME: Lise was invited by an old student friend
to spend Christmas on the west coast of Sweden.
Her nephew, Otto Robert Frisch, who was also a physicist,
came to join her there.
Aunt?
Aunt?
Aunt?
Lise, how are you, my dear?
Merry Christmas.
Aunt?
Hmm, I need your help.
Come on, let's go out.
But I was hoping you'd help me.
LITHGOW: Back in Berlin, Hahn was getting strange results.
He found no evidence to suggest
that bombarding the uranium nucleus with neutrons
had caused it to increase in size.
In fact, his experiments seemed to be contaminated
with radium, a smaller atom.
He desperately needed Meitner's expert analysis.
From afar, she was starting to suspect
that something very different was happening
in their experiment.
Hahn and Strassman are getting some strange results
with the uranium work.
Really?
A couple of months ago, Hahn told me
that they were finding radium amongst the uranium products.
We are looking for a much bigger element,
and... here we're finding something much smaller.
I urged Hahn to check again-- it couldn't be radium.
And now he writes to me
and tells me that it's not radium, it's barium.
But that's even smaller.
Exactly.
Hahn is sure that it's another error,
but I don't know anymore.
It is at least possible that barium is being produced.
So Hahn still needs you to interpret the data.
It is my work, too, you know.
Exactly.
Well, I can't be there, can I?
Come on, let's walk.
Surely he's made a mistake, hasn't he?
He hasn't done what you told him to.
My darling Robert,
he may not be a brilliant theorist,
but he's too good a chemist to get this wrong.
SIME: If you imagine a drop of water-- a big drop--
it's unstable, on the verge of breaking apart.
It turns out that a big nucleus like uranium
is just like that.
Now for four years, Meitner and Hahn
and all other physicists had thought
that if you pump more neutrons into this nucleus,
it'll just get bigger and heavier.
But suddenly, Meitner and Frisch--
out in the midday snow-- realized
this nucleus might just get so big
that it would split in two.
If the nucleus is so big that it has trouble staying together,
then couldn't just a little, tiny jog from a neutron...
Yes, but if the nucleus did split,
the two halves would fly apart with a huge amount of energy.
Where's that energy going to come from?
How much energy?
Well, we worked out that the mutual repulsion between two nuclei
would generate about 200 million electron volts.
But something has to supply that energy.
Wait, let me do a packing fraction calculation.
The two nuclei
are lighter than the original nucleus of the uranium
by about one-fifth of a proton in mass.
What?
So some mass has been lost.
Einstein's E equals m c-squared.
If we multiply the lost mass by the speed of light squared
we get...
( scribbling )
200 million electron volts.
He's split the atom.
No, no, no...
you've split the atom.
SIME: It was an amazing discovery.
Of course, in the laboratory
we're talking about tiny amounts of uranium
and correspondingly tiny amounts of energy.
But the point is that the amount of energy released
was relatively large
and that came from the mass of the uranium itself.
The energy released was entirely consistent
with Einstein's equation E equals m c-squared.
LITHGOW: Meitner and Frisch published the discovery
of what they called "nuclear fission"
to great acclaim.
But betrayal awaited them.
Otto Hahn was under pressure from the Nazi regime
to write his Jewish colleague out of the story.
He alone was awarded the 1944 Nobel Prize for the discovery.
In his speech, he barely mentioned
the leading role of Meitner.
Bizarrely, even after the war,
Hahn maintained it was he and not Meitner
who had discovered nuclear fission.
MEITNER ( composing ): Now, I want to write something personal,
which disturbs me and which I ask you to read
with our more than 40-year friendship in mind
and with the desire to understand me.
I am now referred to as "Hahn's long-time co-worker."
How would you feel if you were only characterized
as the long-time co-worker of me?
After the last 15 years--
which I wouldn't wish on any good friend--
shall my scientific past also be taken from me?
Is that fair?
And why is it happening?
BODANIS: Lise Meitner had been working on this for 30 years.
She'd only broken apart a handful of atoms,
but that was enough.
Once she had broken even one, the genie was out of the bottle.
What Meitner had started... after that,
physicists around the world
began to realize they could take it a lot further.
LITHGOW: In 1942, an intense effort to build an atom bomb was begun.
All over America, secret installations sprang up
under the code name "the Manhattan Project."
Meitner was asked to join the Manhattan Project,
and she refused.
She refused to have anything to do with the atomic bomb.
But Robert Frisch was different.
He was an important member of the team,
because he was convinced of the need
to beat the Nazis in a nuclear arms race.
LITHGOW: A nuclear bomb was never used on Germany,
but the atomic bombs dropped on Hiroshima and Nagasaki
demonstrated the terrible destructive power
of E equals m c-squared.
Vast amounts of energy,
in the form of electromagnetic radiation,
were released from a few pounds of uranium and plutonium.
While the pure inquisitiveness
of the world's most gifted scientists
ironically had brought humanity a weapon of mass destruction,
the equation's life has a parallel story
of creation and beauty.
Today, young physicists carry on Einstein's quest.
Ever since its birth,
E equals m c-squared has been used
to delve into the depths of time,
to answer the biggest question of all--
where did we come from?
At particle accelerators,
researchers propel atomic particles
to the speed of light and smash them together,
creating conditions like those in the Big Bang.
KAISER: E equals m c-squared actually tells us
how the Big Bang itself happened.
In the first moments of creation,
the universe was this immensely dense,
immensely concentrated eruption of energy.
As it rushed apart and expanded, huge amounts of energy, or "E,"
were converted into mass, or "m."
Pure energy became matter--
it became the particles and atoms
and it eventually formed the first stars.
BODANIS: Our sun is a huge furnace floating in space
and it's powered by E equals m c-squared.
Now it turns out, every second,
four million tons of solid mass of the sun disappears.
It comes out as energy.
Not just a little bit of energy.
It's enough to light up our entire solar system,
make the solar system glow with heat and light.
KAKU: And not only do stars emit energy,
in accordance with E equals m c-squared.
The whole process actually creates life itself.
Eventually, a massive star dies,
the debris floats around, clusters together,
gets pulled into the orbits of another star
and becomes a planet.
We humans and the earth we stand on are made of stardust.
We are a direct product of E equals m c-squared.
LITHGOW: Building on the work of scientists through the ages,
new generations are searching for answers.
Using bold new tools that reach almost to the speed of light,
they can now ask questions
that their predecessors could never have even imagined.
As Einstein himself knew,
the journey of discovery is sometimes painful,
sometimes joyful.
It is as old as human curiosity itself
and never, ever ends.
( train whistle blowing )
To order this program on DVD or VHS, or the book,
E = mc2: A Biography of the World's Most Famous Equation,
please call WGBH Boston Video at 1-800-255-9424.
NOVA is a production of WGBH Boston.