This paper presents Chapter
III, section 6 from the book THE EVOLUTION
OF PHYSICS by A. EINSTEIN and L. INFELD. The contents are from the original
publication of this book by Simon and Schuster, New York (1942).
The paragraphs of the original
material (in black) are accompanied by brief comments (in color) based on the present
understanding. Feedback on these comments is appreciated.
The heading below is linked to
the original materials.
.
The
Galilean relativity principle is valid for mechanical phenomena. The same laws
of mechanics apply to all inertial systems moving relative to each other. Is
this principle also valid for non-mechanical phenomena, especially for those
for which the field concepts proved so very important? All problems
concentrated around this question immediately bring us to the starting-point of
the relativity theory.
The Galilean relativity principle applies to a narrow range of velocities of matter. In this range, the velocities are small and inertia is very large (compared to light). Change in inertia corresponding to change in velocity is virtually undetectable. The laws of mechanics are based on this invariability of inertia (mass). All inertial frames exist in this narrow range of velocities of matter.
We
remember that the velocity of light in
vacuo, or in other words, in ether, is 186,000 miles per second and that
light is an electromagnetic wave spreading through the ether. The
electromagnetic field carries energy which, once emitted from its source, leads
an independent existence. For the time being, we shall continue to believe that
the ether is a medium through which electromagnetic waves, and thus also light
waves, are propagated, even though we are fully aware of the many difficulties
connected with its mechanical structure.
The principle of field applies to a broad spectrum of electromagnetic waves. In this spectrum, the inertia (represented by frequencies) is extremely small, but the velocity is very large. Change in velocity corresponding to change in inertia (frequency) is virtually undetectable. The electromagnetic field carries energy which, once emitted from its source, leads an independent existence.
We
are sitting in a closed room so isolated from the external world that no air
can enter or escape. If we sit still and talk we are, from the physical point
of view, creating sound waves, which spread from their resting source with the
velocity of sound in air. If there were no air or other material medium between
the mouth and the ear, we could not detect a sound. Experiment has shown that
the velocity of sound in air is the same in all directions, if there is no wind
and the air is at rest in the chosen c.s.
Let
us now imagine that our room moves uniformly through space. A man outside sees,
through the glass walls of the moving room (or train if you prefer), everything
which is going on inside. From the measurements of the inside observer he can
deduce the velocity of sound relative to his c.s. connected with his
surroundings, relative to which the room moves. Here again is the old, much
discussed, problem of determining the velocity in one c.s. if it is already
known in another.
The
observer in the room claims: the velocity of sound is, for me, the same in all
directions.
The
outside observer claims: the velocity of sound, spreading in the moving room
and determined in my c.s., is not the same in all directions. It is greater
than the standard velocity of sound in the direction of the motion of the room
and smaller in the opposite direction.
These
conclusions are drawn from the classical transformation and can be confirmed by
experiment. The room carries within it the material medium, the air through
which sound waves are propagated, and the velocities of sound will, therefore,
be different for the inside and outside observer.
We
can draw some further conclusions from the theory of sound as a wave propagated
through a material medium. One way, though by no means the simplest, of not
hearing what someone is saying, is to run, with a velocity greater than that of
sound, relative to the air surrounding the speaker. The sound waves produced
will then never be able to reach our ears. On the other hand, if we missed an
important word which will never be repeated, we must run with a speed greater
than that of sound to reach the produced wave and to catch the word. There is
nothing irrational in either of these examples except that in both cases we
should have to run with a speed of about four hundred yards per second, and we
can very well imagine that further technical development will make such speeds
possible. A bullet fired from a gun actually moves with a speed greater than
that of sound and a man placed on such a bullet would never hear the sound of
the shot.
Sound lies in the narrow range of velocities of matter where inertia is very large. Because of high inertia, the wind is substantial. Sound is carried with the wind, so its velocity is higher in the direction of the wind.
All
these examples are of a purely mechanical character and we can now formulate
the important questions: could we repeat what has just been said of a sound wave,
in the case of a light wave? Do the Galilean relativity principle and the
classical transformation apply to optical and electrical phenomena as well as
to mechanical? It would be risky to answer these questions by a simple
“yes” or “no” without going more deeply into their meaning.
In
the case of the sound wave in the room moving uniformly, relative to the
outside observer, the following intermediate steps are very essential for our conclusion:
- The moving room carries the air in which the sound wave is propagated.
- The velocities observed in two c.s. moving uniformly, relative to each other, are connected by the classical transformation.
The
corresponding problem for light must be formulated a little differently. The
observers in the room are no longer talking, but are sending light signals, or light
waves in every direction. Let us further assume that the sources emitting the
light signals are permanently resting in the room. The light waves move through
the ether just as the sound waves moved through the air.
Is
the ether carried with the room as the air was? Since we have no mechanical
picture of the ether, it is extremely difficult to answer this question. If the
room is closed, the air inside is forced to move with it. There is obviously no
sense in thinking of ether in this way, since all matter is immersed in it and
it penetrates everywhere. No doors are closed to ether. The “moving room”
now means only a moving c.s. to which the source of light is rigidly connected.
It is, however, not beyond us to imagine that the room moving with its light
source carries the ether along with it just as the sound source and air were
carried along in the closed room. But we can equally well imagine the opposite:
that the room travels through the ether as a ship through a perfectly smooth
sea, not carrying any part of the medium along but moving through it. In our first
picture, the room moving with its light source carries the ether. An analogy
with a sound wave is possible and quite similar conclusions can be drawn. In
the second, the room moving with its light source does not carry the ether. No
analogy with a sound wave is possible and the conclusions drawn in the case of
a sound wave do not hold for a light wave. These are the two limiting
possibilities. We could imagine the still more complicated possibility that the
ether is only partially carried by the room moving with its light source. But
there is no reason to discuss the more complicated assumptions before finding
out which of the two simpler limiting cases experiment favours.
We
shall begin with our first picture and assume, for the present: the ether is
carried along by the room moving with its rigidly connected light source. If we
believe in the simple transformation principle for the velocities of sound
waves, we can now apply our conclusions to light waves as well. There is no
reason for doubting the simple mechanical transformation law which only states
that the velocities have to be added in certain cases and subtracted in others.
For the moment, therefore, we shall assume both the carrying of the ether by
the room moving with its light source and the classical transformation.
If
I turn on the light and its source is rigidly connected with my room, then the
velocity of the light signal has the well-known experimental value 186,000 miles
per second. But the outside observer will notice the motion of the room, and,
therefore, that of the source—and, since the ether is carried along, his
conclusion must be: the velocity of light in my outside c.s. is different in
different directions. It is greater than the standard velocity of light in the
direction of the motion of the room and smaller in the opposite direction. Our
conclusion is: if ether is carried with the room moving with its light source
and if the mechanical laws are valid, then the velocity of light must depend on
the velocity of the light source. Light reaching our eyes from a moving light
source would have a greater velocity if the motion is toward us and smaller if
it is away from us.
If
our speed were greater than that of light, we should be able to run away from a
light signal. We could see occurrences from the past by reaching previously sent
light waves. We should catch them in a reverse order to that in which they were
sent, and the train of happenings on our earth would appear like a film shown
backward, beginning with a happy ending. These conclusions all follow from the
assumption that the moving c.s. carries along the ether and the mechanical transformation
laws are valid. If this is so, the analogy between light and sound is perfect.
But
there is no indication as to the truth of these conclusions. On the contrary,
they are contradicted by all observations made with the intention of proving them.
There is not the slightest doubt as to the clarity of this verdict, although it
is obtained through rather indirect experiments in view of the great technical
difficulties caused by the enormous value of the velocity of light. The velocity of light is always the same in
all c.s. independent of whether or not the emitting source moves, or how it
moves.
Light lies in the broad spectrum of electromagnetic waves where inertia is extremely small. The “wind” due to moving light source is not substantial at all, and the velocity is extremely large. Therefore, no change in velocity is detected.
We
shall not go into detailed description of the many experiments from which this
important conclusion can be drawn. We can, however, use some very simple arguments
which, though they do not prove that the velocity of light is independent of
the motion of the source, nevertheless make this fact convincing and
understandable.
In
our planetary system the earth and other planets move around the sun. We do not
know of the existence of other planetary systems similar to ours. There are, however,
very many double-star systems, consisting of two stars moving around a point,
called their centre of gravity. Observation of the motion of these double stars
reveals the validity of Newton’s gravitational law. Now suppose that the speed
of light depends on the velocity of the emitting body. Then the message, that is,
the light ray from the star, will travel more quickly or more slowly, according
to the velocity of the star at the moment the ray is emitted. In this case the
whole motion would be muddled and it would be impossible to confirm, in the
case of distant double stars, the validity of the same gravitational law which
rules over our planetary system.
Let
us consider another experiment based upon a very simple idea. Imagine a wheel
rotating very quickly. According to our assumption, the ether is carried by the
motion and takes a part in it. A light wave passing near the wheel would have a
different speed when the wheel is at rest than when it is in motion. The velocity
of light in ether at rest should differ from that in ether which is being
quickly dragged round by the motion of the wheel, just as the velocity of a
sound wave varies on calm and windy days. But no such difference is detected!
No matter from which angle we approach the subject, or what crucial experiment we
may devise, the verdict is always against the assumption of the ether carried
by motion. Thus, the result of our considerations, supported by more detailed
and technical argument, is:
- The velocity of light does not depend on the motion of the emitting source.
- It must not be assumed that the moving body carries the surrounding ether along.
We
must, therefore, give up the analogy between sound and light waves and turn to
the second possibility: that all matter moves through the ether, which takes no
part whatever in the motion. This means that we assume the existence of a sea
of ether with all c.s. resting in it, or moving relative to it. Suppose we leave,
for a while, the question as to whether experiment proved or disproved this
theory. It will be better to become more familiar with the meaning of this new assumption
and with the conclusions which can be drawn from it.
The analogy between sound and light in terms of wind and velocity does not exist. If there is any analogy, it is in terms of a balance between inertia and velocity.
There exists a c.s. resting relative to the ether-sea. In mechanics, not one of the many c.s. moving uniformly, relative to each other, could be distinguished. All such c.s. were equally “good” or “bad”. If we have two c.s. moving uniformly, relative to each other, it is meaningless, in mechanics, to ask which of them is in motion and which at rest. Only relative uniform motion can be observed. We cannot talk about absolute uniform motion because of the Galilean relativity principle. What is meant by the statement that absolute and not only relative uniform motion exists? Simply that there exists one c.s. in which some of the laws of nature are different from those in all others. Also that every observer can detect whether his c.s. is at rest or in motion by comparing the laws valid in it with those valid in the only one which has the absolute monopoly of serving as the standard c.s. Here is a different state of affairs from classical mechanics, where absolute uniform motion is quite meaningless because of Galileo’s law of inertia.
What
conclusions can be drawn in the domain of field phenomena if motion through
ether is assumed? This would mean that there exists one c.s. distinct from all
others, at rest relative to the ether-sea. It is quite clear that some of the
laws of nature must be different in this c.s., otherwise the phrase
“motion through ether” would be meaningless. If the Galilean
relativity principle is valid, then motion through ether makes no sense at all.
It is impossible to reconcile these two ideas. If, however, there exists one
special c.s. fixed by the ether, then to speak of “absolute motion”
or “absolute rest” has a definite meaning.
We
really have no choice. We tried to save the Galilean relativity principle by
assuming that systems carry the ether along in their motion, but this led to a contradiction
with experiment. The only way out is to abandon the Galilean relativity
principle and try out the assumption that all bodies move through the calm ether-sea.
The laws of mechanics based on Galileo’s Relativity principle apply to a very small range of velocities for near constant inertia. Absolute velocities do not exist because the condition of absolute rest is not recognized in this range. But in the wider range, there can be absolute rest for a body of infinite inertia. An example would be a black hole at the center of the galaxy.
The
next step is to consider some conclusions contradicting the Galilean relativity
principle and supporting the view of motion through ether, and to put them to
the test of an experiment. Such experiments are easy enough to imagine, but
very difficult to perform. As we are concerned here only with ideas, we need
not bother with technical difficulties.
Again
we return to our moving room with two observers, one inside and one outside.
The outside observer will represent the standard c.s., designated by the
ether-sea. It is the distinguished c.s. in which the velocity of light always
has the same standard value. All light sources, whether moving or at rest in
the calm ether-sea, propagate light with the same velocity. The room and its
observer move through the ether. Imagine that a light in the centre of the room
is flashed on and off and, furthermore, that the walls of the room are
transparent so that the observers, both inside and outside, can measure the
velocity of the light. If we ask the two observers what results they expect to
obtain, their answers would run something like this:
The outside observer:
My c.s. is designated by the ether-sea. Light in my c.s. always has the
standard value. I need not care whether or not the source of light or other
bodies are moving, for they never carry my ether-sea with them. My c.s. is
distinguished from all others and the velocity of light must have its standard value
in this c.s., independent of the direction of the light beam or the motion of
its source.
The inside observer:
My room moves through the ether-sea. One of the walls runs away from the light and
the other approaches it. If my room travelled, relative to the ether-sea, with
the velocity of light, then the light emitted from the centre of the room would
never reach the wall running away with the velocity of light. If the room
travelled with a velocity smaller than that of light, then a wave sent from the
centre of the room would reach one of the walls before the other. The wall
moving toward the light wave would be reached before the one retreating from
the light wave. Therefore, although the source of light is rigidly connected
with my C.S., the velocity of light will not be the same in all directions. It
will be smaller in the direction of the motion relative to the ether-sea as the
wall runs away, and greater in the opposite direction as the wall moves toward
the wave and tries to meet it sooner.
Thus,
only in the one c.s. distinguished by the ether-sea should the velocity of
light be equal in all directions. For other c.s. moving relatively to the
ether-sea it should depend on the direction in which we are measuring.
The
crucial experiment just considered enables us to test the theory of motion
through the ether-sea. Nature, in fact, places at our disposal a system moving with
a fairly high velocity: the earth in its yearly motion around the sun. If our
assumption is correct, then the velocity of light in the direction of the
motion of the earth should differ from the velocity of light in an opposite
direction. The differences can be calculated and a suitable experimental test
devised. In view of the small time-differences following from the theory, very
ingenious experimental arrangements have to be thought out. This was done in
the famous Michelson-Morley experiment. The result was a verdict of “death”
to the theory of a calm ether-sea through which all matter moves. No dependence
of the speed of light upon direction could be found. Not only the speed of
light, but also other field phenomena would show a dependence on the direction
in the moving c.s., if the theory of the ether-sea were assumed. Every
experiment has given the same negative result as the Michelson-Morley one, and
never revealed any dependence upon the direction of the motion of the earth.
The
situation grows more and more serious. Two assumptions have been tried. The
first, that moving bodies carry ether along. The fact that the velocity of light
does not depend on the motion of the source contradicts this assumption. The
second, that there exists one distinguished c.s. and that moving bodies do not carry
the ether but travel through an ever calm ether-sea. If this is so, then the
Galilean relativity principle is not valid and the speed of light cannot be the
same in every c.s. Again we are in contradiction with experiment.
Michelson-Morley’s experiment simply demonstrated that the motion of Earth through space does not affect the speed of visible light. This result may be interpreted in different ways. But it consistent with almost zero inertia of light and aether. Light is a slightly condensed form of aether. Matter is an extremely condensed form of aether.
More
artificial theories have been tried out, assuming that the real truth lies
somewhere between these two limiting cases: that the ether is only partially
carried by the moving bodies. But they all failed! Every attempt to explain the
electromagnetic phenomena in moving c.s. with the help of the motion of the
ether, motion through the ether, or both these motions, proved unsuccessful.
Thus
arose one of the most dramatic situations in the history of science. All
assumptions concerning ether led nowhere! The experimental verdict was always negative.
Looking back over the development of physics we see that the ether, soon after
its birth, became the enfant terrible
of the family of physical substances. First, the construction of a simple
mechanical picture of the ether proved to be impossible and was discarded. This
caused, to a great extent, the breakdown of the mechanical point of view.
Second, we had to give up hope that through the presence of the ether-sea one
c.s. would be distinguished and lead to the recognition of absolute, and not
only relative, motion. This would have been the only way, besides carrying the
waves, in which ether could mark and justify its existence. All our attempts to
make ether real failed. It revealed neither its mechanical construction nor absolute
motion. Nothing remained of all the properties of the ether except that for
which it was invented, i.e. its ability to transmit electromagnetic waves. Our attempts
to discover the properties of the ether led to difficulties and contradictions.
After such bad experiences, this is the moment to forget the ether completely and
to try never to mention its name. We shall say: our space has the physical
property of transmitting waves, and so omit the use of a word we have decided
to avoid.
According to Einstein, aether is an invented concept. All we can say is that our space has the physical property of transmitting waves. Einstein then expresses the idea of space mathematically only.
The
omission of a word from our vocabulary is, of course, no remedy. Our troubles
are indeed much too profound to be solved in this way!
Let
us now write down the facts which have been sufficiently confirmed by
experiment without bothering any more about the “e——- r ” problem.
(1)
The velocity of light in empty space always has its standard value, independent
of the motion of the source or receiver of light.
(2)
In two c.s. moving uniformly, relative to each other, all laws of nature are
exactly identical and there is no way of distinguishing absolute uniform
motion.
There
are many experiments to confirm these two statements and not a single one to
contradict either of them. The first statement expresses the constant character
of the velocity of light, the second generalizes the Galilean relativity
principle, formulated for mechanical phenomena, to all happenings in nature.
In
mechanics, we have seen: If the velocity of a material point is so and so,
relative to one c.s., then it will be different in another c.s. moving
uniformly, relative to the first. This follows from the simple mechanical transformation
principles. They are immediately given by our intuition (man moving relative to
ship and shore) and apparently nothing can be wrong here! But this
transformation law is in contradiction to the constant character of the
velocity of light. Or, in other words, we add a third principle:
(3)
Positions and velocities are transformed from one inertial system to another
according to the classical transformation.
The
contradiction is then evident. We cannot combine (1), (2), and (3).
The
classical transformation seems too obvious and simple for any attempt to change
it. We have already tried to change (1) and (2) and came to a disagreement with
experiment. All theories concerning the motion of “e——- r”
required an alteration of (1) and (2). This was no good. Once more we realize
the serious character of our difficulties. A new clue is needed. It is supplied
by accepting the fundamental assumptions (1)
and (2), and, strange though it
seems, giving up (3). The new clue
starts from an analysis of the most fundamental and primitive concepts; we
shall show how this analysis forces us to change our old views and removes all
our difficulties.
Einstein’s assumptions may be criticized as follows: (1) Light is a substance of almost zero inertia; whereas, the source of light is considered to be a material object of extremely high inertia. The velocity of light is so high that variations in it due to changes in frequency cannot be detected in the framework of matter. (2) The idea of c.s. is limited to a narrow range of velocities for which inertia is so large that changes in it corresponding to changes in velocity cannot be detected. Based on inertia we can say that the velocity of light intuitively applies to “sunlight relative to the sun” and not to “sun relative to the sunlight.” (3) The laws of classical mechanics are a very small subset of the laws of nature under conditions as described above. The classical viewpoint does not consider the balance in nature between velocity and inertia.
Velocities can be differentiated as being greater or lesser on an absolute basis by comparing the inertia of the particles.
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Final Comment
According to the Galilean relativity principle of mechanical phenomena, it is impossible to say which particle is at rest relative to the other. But we have no such difficulty in intuitively recognizing that the Sun is at rest relative to the sunlight and not the opposite. This intuition has its basis in the concept of inertia.
The problem with the laws of classical mechanics is that they are limited to the assumption that the only substance is matter that has a fixed level of inertia (mass). Classical mechanics does not recognize that from matter to aether, there is a spectrum of substance with a gradation of inertia, and that the relative velocity is a manifestation of that inertia. The lesser is the inertia, the greater is the inherent velocity of substance.
Science assumes that all material systems have the same inertia (mass) for different velocities. It then makes another assumption that all electromagnetic systems have the same velocity for different levels of inertia (frequencies). Both assumptions are approximations for two extremes. Einstein’s theory predicts velocities for situations close to these extremes by extrapolating between these two extremes. But that extrapolation does not predict velocities correctly for situations farther away from these extremes.
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