Einstein's Physics Of Illusion

Some of you may think from the title "Einstein's Physics of Illusion", that I'm going to talk about the
physics which underlies what we think of as magic. That is not what I expect to talk about. Some of you
may think that I suspect that Einstein had some special physics of illusions. If he did, I don't know
anything of it. Instead, what I want to do, with Einstein's help, is to trace our physics all the way back to
square one, and to find out whether, underlying it, there may possibly be something akin to magic.
George Valens has written a charming book called The Attractive Universe. It is subtitled "Gravity and
the Shape of Space", and on the very first page he says that when a ball is thrown straight up, after a
while it comes to a stop, changes its direction and comes back. He says it looks like magic, and probably
it is. Now what he is taking for granted is that it should have gone off on a straight path without any
change in speed or direction. But you see, that also would have been the result of magic. We do not
understand in physics why the ball comes back. But we also do not understand in our physics why the
ball should have continued without any change in the direction of its speed....
Now in the title, and in the remarks that I have made so far, what I mean by magic or illusion is
something like what happens when, in the twilight, you mistake a rope for a snake. And this sort of thing
was analyzed very carefully by some people in North India long, long ago, and they said that when you
make such a mistake there are three aspects to your mistake. First, you must fail to see the rope rightly.
Then, instead of seeing it as a rope, you must see it as something else. And finally, you had to see the
rope in first place or you never would have mistaken it for" a snake. You mistook it for a snake because
the rope was three feet long, and you're accustomed to three foot long snakes.
But before I speak further about illusion, I want to say a few words about what we do understand in
physics, and I also want to point out a few gaps in that understanding. When we talk about the universe,
or when we look out and see it, what we see is that the universe is made out of what we call matter. It's
what we call a material universe. And what we want to do, first of all, is to trace that material back, not
quite to square one, but to square two at least, We want to find out whether we can think of all these
things which we see as being made out of matter, as really being made out of only a few ingredients.
And the answer is that we can. Long ago the chemists pointed out that all these things that we see are
made out of not more than 92 ingredients. Those are the 92 chemical elements of the periodic table. It
was suggested in 1815 that all those different chemical elements are probably made out of hydrogen.
That was Prout's hypothesis, because in those days no one knew how to do it. But now, in modern times, we do know how to do it, and we do know that that's what happens. All the other chemical elements
are made out of hydrogen, and it happens in the stars"
The universe, even as it is today, consists mostly of hydrogen. And what it is doing is falling together in
the gravitational field. It falls together to galaxies and stars, and the stars are hot. Falling together by
gravity is what makes them hot. And they get hot enough inside so that the hydrogen is converted
to.helium. Now helium is a very strong atomic nucleus, and so the main line in building up the atoms of
the atomic table goes this way: First, four hydrogens make one helium. Then three heliums make one
carbon. Two heliums won't stick. That would be beryllium-8. There is no beryllium-8. It won't last. But
three heliums will stick, and that's carbon. Four is oxygen. Five is neon. That's the way it goes in the
stars; the other nuclei are built of helium nuclei. Six makes magnesium. Then silicon, sulfur, argon,
calcium, titanium, chromium and iron.
In big stars it goes like this. But in small stars like our sun it goes only up to carbon or possibly carbon
and oxygen. That's where our sun will end, at about the size of the earth, but with a density of about four
concrete mixing trucks in a one pint jar. Larger stars get too hot by their own gravitational squeeze, and
the carbon cannot cool off like that. They go right on to oxygen and so on, until they get, in the center, to
iron. Now iron is the dumbest stuff in the universe. There is no nuclear energy available to iron --
nothing by which it can fight back against gravitational collapse; so gravity collapses it, this time to the
density of a hundred thousand airplane carriers squeezed into a one pint yogurt box One hundred
thousand airplane carriers in a one pint box! And, when it collapses like that, the gravitational energy that
is released to other forms blows the outer portions of the star all over the galaxy. That's the stuff out of
which our bodies are made. Our bodies are all made out of star dust from such exploding stars.
We do know that the main ingredient of the universe is hydrogen and that the main usable energy in the
universe is gravitational. We know that the name of the game is falling together by gravity (hydrogen,
falling together by gravity), but what we don't know is why things fall together by gravity. We do know
that the stuff out of which this universe is made is hydrogen, but we do not know from where we get
the hydrogen. We know that the hydrogen is made of electrical particles, protons and electrons, and we
know that the total electrical charge of the universe is zero, but we do not know, you see, why it is made
of electricity. We do not know why it falls together. And we do not know why, when things are
moving, they should coast. There are these gaps in our understanding. We know how things coast. We
know how things fall. We know how the electrical particles behave, but we don't know any of the why
questions. We don't have any answers to the why questions.
What I want to talk about next is a discovery made by Albert Einstein when he was 26 years old and
working in the patent office in Bern. Then I want to talk about the" consequences of that discovery and,
through that, I want to trace our physics back, if possible, to answer those why questions.
Einstein noticed that we cannot have an objective universe in three dimensions. We all talk about 3-D.
Hardly anybody talks about 4-D. But the universe is 4-D. It is not possible to have a universe of space
without a universe of time. It is not possible to have space without time, or time without space, because
space and time are opposites. I don't know that Einstein ever used the language that space and time are
opposites, but if you look at his equations, it is very, very clear that that's exactly what they are. If,
between two events, the space separation between them is the same as the time separation between them,
then the total separation between them is zero. That's what we mean by opposites in this case. In
electricity if we have the same amount of plus charges as we have of minus charges, say in the same atom or the same molecule, then that atom or that molecule is neutral. There is no charge seen from
outside. Likewise here. If the space separation between, two events is just the same as the time separation
between those two events, then the total separation between those two events is zero.
I'll give you an example. Suppose we see an exploding star, say in the Andromeda galaxy. There's one
going on there right now. It's been visible for about a month or so. Now the Andromeda galaxy is two
and a quarter million light years away, and when we see the explosion now, we see it as it was two and a
quarter million years ago. You see, the space separation and the time separation are the same, which
means that the total separation between you and what you see is zero. The total separation, the real
separation, the objective separation, that is, the separation as seen by anybody, between the event
which you see and the event of your seeing it -- the separation between those two events is always zero.
What we mean when we say that the space and time separations between two events are equal is that
light could get from one of those events to the other in vacuum.
We see things out there, and we think they're really out there. But, you see, we cannot see them when
they happen. We can't see anything when it happens. We see everything in the past. We see everything a
little while ago, and always in such a way that the while ago just balances the distance away, and the
separation between the perceiver and the perceived remains always at zero.
As soon as Einstein noticed that we cannot have a universe of space without a universe of time and vice
versa, and that they are connected in this way, and that the only way to have an objective universe is in
four dimensions, and not in two or three or one -- as soon as he noticed that, he had to redo our physics.
Now relativity theory is a geometry theory. It's not something else. It's a geometry theory. It's about the
geometry of the real world. I'm sure that most if not all of you have been exposed, somewhere along your
educational careers, to the geometry of Euclid. His geometry is in two dimensions and in three, but he
didn't have any idea about introducing the fourth dimension. His geometry - is a theoretical geometry
about a theoretical space which does not, in fact, exist. Newton based his understanding of physics also
on that understanding of geometry, and Newton's physics is a theoretical physics about a theoretical
universe which does not, in fact, exist. We know now, you see, that Euclid was wrong in his
understanding of geometry, and that Newton was likewise wrong in his understanding of physics. And
we had to correct our physics in terms of Einstein's re-understanding of geometry. It was when Einstein
went through our physics with his new understanding of geometry that he saw that what we had been
calling matter or mass or inertia is really just energy. It is just potential energy. It had been suggested a
few years earlier by Swami Vivekananda that what we call matter could be reduced to potential energy.
In about 1895 he writes in a letter that he is to go the following week to see Mr. Nikola Tesla who thinks
he can demonstrate it mathematically. Without Einstein's understanding of geometry, however, Tesla
apparently failed.
It was from the geometry that Einstein saw that what we call rest mass, that which is responsible for the
heaviness of things and for their resistance to being shaken, is really just energy. Einstein's famous
equation is E = mc2. Probably most of you have seen that equation. It says that for a particle at rest, its
mass is equal to its energy. Those of you who read Einstein know that there is no "c" in that equation.
The c2 is just in case your units of space and time don't match. If you've chosen to measure space in an
arbitrary unit and time in another arbitrary unit, and if you have not taken the trouble to connect the two
units, then, for your system you have to put in the c2. If you're going to measure space in centimeters,
then time must not be measured in seconds. It must be measured in jiffies. A jiffy is the length of time it takes light to go one centimeter. Astronomers are rather broad minded people, and they have noticed that
the universe is quite a bit too big to be measured conveniently in centimeters, and quite a bit too old to be
measured conveniently in seconds; so they measure the time in years and the distance in light-years, and
the units correspond. That "c" in the equation is the speed of light in your system of units, and if you've
chosen years and light-years then the speed of light in your system is one. And if you square it, it's still
one, and the equation doesn't change. The equation simply says that energy and mass are the same thing.
Our problem now is that if we're going to trace this matter back, and find out what it is, we have first of
all to find out what kind of energy makes it massive. Now we have only a few kinds of energy to choose
from. Fortunately there are only a few: gravitational energy, kinetic energy, radiation, electricity,
magnetism and nuclear energy. But I must allay your suspicion that nuclear energy might be very
important. It is not. The nuclear energy available in this universe is very small. If all the matter in the
universe began as hydrogen gas and ended as iron, then the nuclear energy released in that change (and
that is the maximum nuclear energy available) is only one per cent of what you can get by letting that
hydrogen fall together by gravity. So nuclear energy is not a big thing, and we have only five kinds of
energy to choose from in order to find out what kind of energy makes the primordial hydrogen hard to
shake. That, you remember, was our problem.
What we want is potential energy, because the hydrogen is hard to shake even when it's not doing a
thing. So what we're after is potential energy, and that restricts it quite a bit more. Radiation has nothing
to do with that. Radiation never stands still. And kinetic energy never stands still. And even magnetic
energy never stands still. So we are left with electricity and gravity. There are only two. We don't have
any choice at all. There is just the gravitational energy and the electrical energy of this universe available
to make this universe as heavy or as massive as we find it.
Now I should remind you that the amount of energy we're talking about is very large. It's five hundred
atom bombs per pound. One quart of yogurt, on the open market, is worth one thousand atom bombs. It
just happens that we're not in the open market place. We live where we have no way to get the energy of
that yogurt to change form to kinetic energy or radiation so that we can do anything with it. It's tied up in
there in such a way that we can't get it out. But right now we're going to talk about the possibility of
getting it out. We want to talk about how this tremendous energy is tied up in there. We want to talk
about how this matter is "wound up".
First let's talk about watches. We know how they're wound up. They're wound up against a spring. Now
when we wind up a watch, what I want to know is whether it gets heavier or lighter. If we have a watch,
and if we wind it up, does it get harder to shake or easier? It gets harder to shake because when we wind
it up we put more potential energy into it, and energy is the only thing in the universe that's hard to
shake. So now we want to know in what way the whole universe is wound up to make it heavy and hard
to shake. We know that it must be wound up against electricity and gravity. The question is: How?
We need to know some details on how to wind things up. How, for instance, do you wind up against
gravity? You wind against gravity by pulling things apart in the gravitational field. They all want to go
back together again. And if the entire universe were to fall together to a single blob, the gravitational
energies that would be released to other forms would be five hundred atom bombs per pound. The
universe is wound up on gravitational energy just by being spaced away from itself against the
gravitational pull inward. And it turns out to be just the right amount. It really does account for the fact
that it's five hundred atom bombs per pound.