Classic Audiobook Collection - The Einstein Theory of Relativity by Hendrik A. Lorentz ~ Full Audiobook [science]
Episode Date: October 23, 2023The Einstein Theory of Relativity by Hendrik A. Lorentz audiobook. Genre: science When Albert Einstein published his first paper on relativity theory, it caused a stir in the physicists' community. W...hen more and more evidence was gathered to prove the theory correct, even laymen became interested in it. Since the theory of relativity uses involved higher mathematics, it is considered notoriously difficult to grasp, and at the time it was published, it was claimed that only 12 people in the world were able to fully understand it. One of these was the Dutch physicist Hendrik Lorentz, who wrote the articles collected in this book for a lay audience. He explains the basics of the theory in clear and concise terms without needing any mathematics. All that is needed to fo follow his arguments is a bit of patience and time. For ad-free listening try our premium subscription Chapters (Approximate) (00:00:00) Chapter 1 (00:17:59) Chapter 2 (00:22:09) Chapter 3 (00:27:18) Chapter 4 (00:32:59) Chapter 5 (00:39:47) Chapter 6 (00:48:20) Chapter 7 Learn more about your ad choices. Visit megaphone.fm/adchoices
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The Einstein Theory of Relativity by Hendrik A. Lorenz.
Section 1.
Note
Whether it is true or not that not more than 12 persons in all the world are able to understand Einstein's theory,
it is nevertheless a fact that there is a constant demand for information about this much-debated topic of relativity.
The books published on the subject are so technical that only a person trained in
in pure physics and higher mathematics is able to fully understand them.
In order to make a popular explanation of this far-reaching theory available,
the present book is published.
Professor Lorenz is credited by Einstein with sharing the development of his theory.
He is doubtless better able than any other man, except the author himself,
to explain this scientific discovery.
The publishers wish to acknowledge their indebted
to the New York Times, the Review of Reviews, and the Athenium for courteous permission to reprint articles from their pages.
Professor Lorenz's article appeared originally in the newer Rotterdam's Churant of November 1919.
Introduction
The action of the Royal Society at its meeting in London on November 6th in recognizing Dr. Albert Eindon,
Einstein's theory of relativity has caused a great stir in scientific circles on both sides of the Atlantic.
Dr. Einstein propounded his theory nearly 15 years ago.
The present revival of interest in it is due to the remarkable confirmation which it received in the report of the observations
made during the sun's eclipse of last May to determine whether rays of light passing close to the sun are deflected from
their course. The actual deflection of the rays that was discovered by the astronomers was precisely
what had been predicted theoretically by Einstein many years since. This striking confirmation
has led certain German scientists to assert that no scientific discovery of such importance
has been made since Newton's theory of gravitation was promulgated. This suggestion, however,
was put aside by Dr. Einstein himself
when he was interviewed by a correspondent of the New York Times
at his home in Berlin.
To this correspondent, he expressed a difference
between his conception and the law of gravitation
in the following terms.
Please imagine the earth removed
and in its place suspended a box as big as a room
or a whole house,
and inside a man naturally floating in the center.
there being no force whatever pulling him.
Imagine further, this box being, by a rope or other contrivance,
suddenly jerked to one side,
which is scientifically termed deform motion,
as opposed to uniform motion.
The person would then naturally reach bottom on the opposite side.
The result would consequently be the same
as if he obeyed Newton's law of gravitation,
while, in fact, there is no gravitation exerted whatever,
which proves that deform motion will in every case produce the same effects as gravitation.
I have applied this new idea to every kind of deform motion
and have thus developed mathematical formulas,
which I am convinced give more precise results than those based on Newton's theory.
Newton's formulas, however, are such close approximations
that it was difficult to find by observation any obvious disagreement with experience.
Dr. Einstein, it must be remembered, is a physicist and not an astronomer.
He developed his theory as a mathematical formula.
The confirmation of it came from the astronomers.
As he himself said, the crucial test was supplied by the last total solar eclipse.
observations then proved that the rays of fixed stars, having to pass close to the sun to reach the earth,
were deflected the exact amount demanded by Einstein's formulas.
The deflection was also in the direction predicted by him.
The question must have occurred to many, what has all this to do with relativity?
When this query was propounded by the Times correspondent to Dr. Einstein, he replied as
follows. The term relativity refers to time and space. According to Galileo and Newton,
time and space were absolute entities, and the moving systems of the universe were dependent
on this absolute time and space. On this conception was built the science of mechanics. The resulting
formulas sufficed for all motions of a slow nature. It was found, however, that they would not
conform to the rapid motions apparent in electrodynamics.
This led the Dutch professor, Lorenz, and myself, to develop the theory of special relativity.
Briefly, it discards absolute time and space and makes them in every instance relative to moving systems.
By this theory, all phenomena in electrodynamics, as well as mechanics, hitherto irreducible by the old
formulae, and there are multitudes, were satisfactorily explained.
Till now it was believed that time and space existed by themselves,
even if there was nothing else, no sun, no earth, no stars,
while now we know that time and space are not the vessel for the universe,
but could not exist at all if there were no contents,
namely no sun, earth, and other celestial bodies.
This special relativity, forming the first part of my theory,
relates to all systems moving with uniform motion,
that is, moving in a straight line with equal velocity.
Gradually I was led to the idea,
seeming a very paradox in science,
that it might apply equally to all moving systems,
even of deform motion,
and thus I developed the conception of general relativity,
which forms the second part of my theory.
As summarized by an American astronomer,
Professor Henry Norris Russell of Princeton
in the Scientific American for November 29,
Einstein's contribution amounts to this.
The central fact which has been proved
and which is of great interest and importance
is that the natural phenomena involving gravitation and inertia,
such as the motions of the planet,
and the phenomena involving electricity and magnetism, including the motion of light,
are not independent of one another, but are intimately related,
so that both sets of phenomena should be regarded as parts of one vast system
embracing all nature.
The relation of the two is, however, of such a character that it is perceptible only in a very few instances,
and then only to refined observations.
Already before the war, Einstein had immense fame among physicists
and among all who are interested in the philosophy of science
because of his principle of relativity.
Clark Maxwell had shown that light is electromagnetic
and had reduced the whole theory of electromagnetism
to a small number of equations,
which are fundamental in all subsequent work.
But these equations were entangled with the hypothesis of the ether and was the notion of motion relative to the ether.
Since the ether was supposed to be addressed, such motion was indistinguishable from absolute motion.
The motion of the earth relatively to the ether should have been different at different points of its orbit,
and measurable phenomena should have resulted from this difference.
but none did, and all attempts to detect effects of motions relative to the ether failed.
The theory of relativity succeeded in accounting for this fact,
but it was necessary incidentally to throw over the one universal time
and substitute local times attached to moving bodies and varying according to their motion.
The equations on which the theory of relativity is based are,
due to Lorenz, but Einstein connected them with his general principle, namely that there must
be nothing in observable phenomena which could be attributed to absolute motion of the observer.
In orthodox Newtonian dynamics, the principle of relativity had a simpler form, which did not
require the substitution of local time for general time. But it now appeared that Newtonian dynamics is
only valid when we confine ourselves to velocities much less than that of light.
The whole Galileo-Nuton system thus sank to the level of a first approximation,
becoming progressively less exact as the velocities concerned approached that of light.
Einstein's extension of his principle so as to account for gravitation was made during the war,
and for a considerable period our astronomers were unable to become acquainted with it,
owing to the difficulty of obtaining German printed matter.
However, copies of his work ultimately reached the outside world
and enabled people to learn more about it.
Gravitation, ever since Newton, had remained isolated from other forces in nature.
Various attempts had been made to account for it, but without success.
The immense unification affected by electromagnetism apparently left gravitation out of its scope.
It seemed that nature had presented a challenge to the physicists which none of them were able to meet.
At this point Einstein intervened with a hypothesis, which, apart altogether from subsequent verification,
deserves to rank as one of the great monuments of human genius.
After correcting Newton, it remained to correct Euclid,
and it was in terms of non-Euclidean geometry that he stated his new theory.
Non-Euclidean geometry is a study of which the primary motive was logical and philosophical.
Few of its promoters ever dreamed that it would come to be applied in physics.
Some of Euclid's axioms were felt to be not necessary truths,
but mere empirical laws.
In order to establish this view,
self-consistent geometries
were constructed upon assumptions
other than those of Euclid.
In these geometries,
the sum of the angles of a triangle
is not two right angles,
and the departure from two right angles
increases as the size of the triangle increases.
It is often said
that in non-Euclidean geometry,
space has a curvature, but this way of stating the matter is misleading,
since it seems to imply a fourth dimension which is not implied by these systems.
Einstein supposes that space is Euclidean where it is sufficiently remote from matter,
but that the presence of matter causes it to become slightly non-Euclidean.
The more matter there is in the neighborhood, the more space will depart from Euclid.
By the help of this hypothesis, together with his previous theory of relativity,
he deduces gravitation, vary approximately, but not exactly,
according to the Newtonian law of the inverse square.
The minute differences between the effects deduced from his theory
and those deduced from Newton are measurable in certain cases.
There are, so far, three crucial tests of,
the relative accuracy of the new theory and the old.
1. The perihelion of Mercury shows a discrepancy which has long-puzzled astronomers.
This discrepancy is fully accounted for by Einstein.
At the time when he published his theory, this was its only experimental verification.
2. Modern physicists were willing to suppose that light might be subject
to gravitation, i.e. that a ray of light passing near a great mass like the sun
might be deflected to the extent to which a particle moving with the same velocity
would be deflected according to the orthodox theory of gravitation. But Einstein's theory
required that the light should be deflected just twice as much as this. The matter could
only be tested during an eclipse
among a number of bright stars.
Fortunately, a
peculiarly favorable eclipse
occurred last year.
The results of the observations
have now been published and are
found to verify Einstein's
prediction. The verification
is not, of course,
quite exact, with such
delicate observations that was not
to be expected. In some
cases, the departure is considerable.
But, the
Taking the advantage of the best series of observations,
the deflection at the sun's limb is found to be 1.98 seconds,
with a probable error of about 6%,
whereas the deflection calculated by Einstein's theory
should be 1.75 seconds.
It will be noticed that Einstein's theory
gave a deflection twice as large as that predicted by the Orthodox theory,
and that the observed deflection is slightly larger than Einstein predicted.
The discrepancy is well within what might be expected in view of the minuteness of the measurements.
It is therefore generally acknowledged by astronomers that the outcome is a triumph for Einstein.
3.
In the excitement of this sensational verification, there has been a tendency to overlook the third experimental test
to which Einstein's theory was to be subjected.
If his theory is correct as it stands,
there ought, in a gravitational field,
to be a displacement of the lines of the spectrum towards the red.
No such effect has been discovered.
Spectroscopists maintain that,
so far as can be seen at present,
there is no way of accounting for this failure
if Einstein's theory in its present form is assumed.
They admit that some compensating cause may be discovered to explain the discrepancy,
but they think it far more probable that Einstein's theory requires some essential modification.
Meanwhile, a certain suspense of judgment is called for.
The new law has been so amazingly successful in two of the three tests
that there must be something valid about it,
even if it is not exactly right as yet.
Einstein's theory has the very highest degree of aesthetic merit.
Every lover of the beautiful must wish it to be true.
It gives a vast unified survey of the operations of nature,
with a technical simplicity in the critical assumptions
which makes the wealth of deductions astonishing.
It is a case of an advance arrived at by pure theory.
The whole effect of Einstein's work is to make physical,
more philosophical, in a good sense, and to restore some of that intellectual unity which belonged to the great
scientific systems of the 17th and 18th centuries, but which was lost through increasing specialization
and the overwhelming mass of detailed knowledge. In some ways our age is not a good one to live in,
but for those who are interested in physics, there are great compensations.
Section 2 of
The Einstein Theory of Relativity by
Hendrik A. Lorenz.
This Librivox recording is in the public domain.
Recording by Abayi in February 2020.
The Einstein Theory of Relativity,
a concise statement by Professor H. A.
Lorenz of the University of Leiden.
The total eclipse of the sun on May 29th
resulted in a striking confirmation of the new theory of the universal attractive power of gravitation
developed by Albert Einstein, and thus reinforced the conviction that the defining of this theory
is one of the most important steps ever taken in the domain of natural science.
In response to a request by the editor, I will attempt to contribute something to its general appreciation in the following lines.
For centuries, Newton's doctrine of the attraction of gravitation has been the most prominent example of a theory of natural science.
Through the simplicity of its basic idea, an attraction between two bodies proportionate to their mass and also proportionate to the square of the distance,
through the completeness with which it explained so many of the peculiarities in the movement of the bodies making up the solar system,
And finally, through its universal validity, even in the case of the far-distant planetary systems,
it compelled the admiration of all.
But while the skill of the mathematicians was devoted to making more exact calculations of the consequences to which it led,
no real progress was made in the science of gravitation.
It is true that the inquiry was transferred to the field of physics,
following Cavendish's success in demonstrating the common attraction between bodies with which laboratory work can be done,
but it always was evident that natural philosophy had no grip on the universal power of attraction.
While in electric effects an influence exercised by the matter placed between bodies was speedily observed,
the starting point of a new and fertile doctrine of electricity,
in the case of gravitation, not a trace of an influence exercised by intermediate matter could ever be discovered.
It was, and remained, inaccessible and unchangeable, without any connection, apparently, with other phenomena of natural philosophy.
Einstein has put an end to this isolation.
It is now well established that gravitation effects not only matter, but also life.
light. Thus strengthened in the faith that his theory already has inspired, we may assume with
him that there is not a single physical or chemical phenomenon which does not feel, although
very probably in an unnoticeable degree, the influence of gravitation, and that, on the other
side, the attraction exercised by a body is limited in the first place by the quantity of matter
it contains, and also, to some degree, by motion, and by the physical and chemical condition
in which it moves.
It is comprehensible that a person could not have arrived at such a far-reaching change
of view by continuing to follow the old beaten paths, but only by introducing some sort
of new idea.
Indeed, Einstein arrived at his theory through a train of thought of great old.
originality. Let me try to restate it in concise terms.
End of Section 2.
Section 3 of The Einstein Theory of Relativity by Hendrik A. Lorenz.
This Librivox recording is in the public domain.
Recording by Hawaii in February 2020.
The Earth as a Moving Car
Everyone knows that a person may be sitting in any kind of
vehicle without noticing its progress, so long as the movement does not vary in direction
or speed. In a car of a fast express train, objects fall in just the same way as in a coach
that is standing still. Only when we look at objects outside the train, or when the air can
enter the car, do we notice indications of the motion. We may compare the earth with such a moving
vehicle, which in its course around the sun has a remarkable speed, of which the direction
and velocity during a considerable period of time may be regarded as constant.
In place of the air now comes, so it was reasoned formally, the ether, which fills the spaces
of the universe and is the carrier of light and of electromagnetic phenomena.
There were good reasons to assume that the Earth was entirely permeable, and the Earth was entirely
permeable for the ether and could travel through it without setting it in motion.
So here was a case comparable with that of a railroad coach open on all sides.
There certainly should have been a powerful ether wind blowing through the earth and all
our instruments, and it was to have been expected that some signs of it would be noticed
in connection with some experiment or other.
Every attempt along that line, however, has remained fruitless.
All the phenomena examined were evidently independent of the motion of the earth.
That this is the way they do function was brought to the front by Einstein in his first or special theory of relativity.
For him, the ether does not function, and in the sketch that he draws of natural phenomena,
there is no mention of that intermediate matter.
If the spaces of the universe are filled with an ether,
let us suppose with a substance in which,
aside from eventual vibrations and other slight movements,
there is never any crowding or flowing of one part alongside of another,
then we can imagine fixed points existing in it.
For example, points in a straight line, located one meter apart,
points in a level plane, like the angles or squares on a chessboard extending out into infinity,
and finally, points in space, as they are obtained by repeatedly shifting that level spot
a distance of a meter in the direction perpendicular to it.
If, consequently, one of the points is chosen as an original point,
we can, proceeding from that point, reach any other other point.
a point through three steps in the common perpendicular directions in which the points are arranged.
The figures showing how many meters are comprised in each of the steps may serve to indicate
the place reached and to distinguish it from any other. These are, as is said, the coordinates of
these places, comparable, for example, with the numbers on a map giving the longitude and latitude.
Let us imagine that each point has noted upon it the three numbers that give its position.
Then we have something comparable with a measure with numbered subdivisions.
Only we now have to do, one might say, with a good many imaginary measures in three common perpendicular directions.
In this system of coordinates, the numbers that fix the position of one or the other of the bodies may now be read off at any moment.
moment. This is the means which the astronomers and their mathematical assistants have always used in
dealing with the movement of the heavenly bodies. At a determined moment, the position of each body
is fixed by its three coordinates. If these are given, then one knows also the common distances,
as well as the angles formed by the connecting lines, and the movement of a planet is to be known
as soon as one knows how its coordinates are changing from one moment to the other.
Thus, the picture that one forms of the phenomena stands there
as if it was sketched on the canvas of the motionless ether.
End of Section 3.
Section 4 of The Einstein Theory of Relativity by Hendrik A. Lorenz.
This Librevox recording is in the public domain,
recording by Hawaii in February 2000.
Einstein's departure.
Since Einstein has cut loose from the ether, he lacks this canvas,
and therewith, at the first glance, also loses the possibility of fixing the positions
of the heavenly bodies and mathematically describing their movement,
that is, by giving comparisons that define the positions at every moment.
How Einstein has overcome this difficulty,
be somewhat elucidated through a simple illustration.
On the surface of the earth, the attraction of gravitation causes all bodies to fall along
vertical lines, and indeed, when one omits the resistance of the air with an equally accelerated
movement, the velocity increases in equal degrees in equal consecutive divisions of time,
a rate that in this country gives the velocity attained at the end of a second as
981 centimeters, 32.2 feet per second. The number 981 defines the acceleration in the field of
gravitation and this field is fully characterized by that single number. With its help
we can also calculate the movement of an object hurled out in an
arbitrary direction. In order to measure the acceleration, we let the body drop
alongside of a vertical measure set solidly on the ground. On this scale we read at
every moment the figure that indicates the height, the only coordinate that is of
importance in this rectilinear movement. Now we ask what would we be able to see
if the measure were not bound solidly to the earth, if it let us
us suppose, moved down or up with the place where it is located and where we are ourselves.
If in this case the speed were constant, then, and this is in accord with the special theory of
relativity, there would be no motion observed at all. We should again find an acceleration of
981 for a falling body. It would be different if the measure moved with changeable velocity.
If it went down with a constant acceleration of 981 itself,
then an object could remain permanently at the same point on the measure,
or could move up or down itself alongside of it with constant speed.
The relative movement of the body with regard to the measure
should be without acceleration,
and if we had to judge only by what we observed in the spot where we were,
and which was falling itself,
then we should get the impression
that there was no gravitation at all.
If the measure goes down with an acceleration
equal to a half or a third of what it just was,
then the relative motion of the body will, of course, be accelerated,
but we should find the increase in velocity per second
one-half or two-thirds of 981.
If, finally, we let the measure rise with a uniformly accelerated movement,
then we shall find a greater acceleration than 981 for the body itself.
Thus we see that we, also when the measure is not attached to the earth,
disregarding its displacement, may describe the motion of the body
in respect to the measure always in the same way,
That is, as one uniformly accelerated, as we as we ascribe now and again a fixed value to the acceleration of the sphere of gravitation, in a particular case the value of zero.
Of course, in the case here under consideration, the use of a measure fixed immovably upon the Earth should merit all recommendation.
But in the spaces of the solar system we have, now that we have abandoned de-ether, no such support.
We can no longer establish a system of coordinates, like the one just mentioned, in a universal
intermediate matter, and if we were to arrive in one way or another at a definite system of
lines crossing each other in three directions, then we should be able to use just as well
another similar system that in respect to the first moves this or that way.
We should also be able to remodel the system of coordinates in all kinds of ways,
for example by extension or compression.
That in all these cases for fixed bodies that do not participate in the movement
or the remodeling of the system, other coordinates will be read off again and again is clear.
End of Section 4.
Section 5 of The Einstein Theory of Relativity by Hendrik A. Lorenz.
This Librivox recording is in the public domain.
Recording by Abayi in February 2020.
New system or coordinates.
What way Einstein had to follow is now apparent.
He must, this hardly needs to be said, in calculating
definite particular cases make use of a chosen system of coordinates, but as he had no means of
limiting his choice beforehand and in general, he had to reserve full liberty of action in this
respect. Therefore, he made it his aim so to arrange the theory that, no matter how the choice
was made, the phenomena of gravitation, so far as its effects and its stimulation by the
attracting bodies are concerned, may always be described in the same way, that is, through
comparisons of the same general form, as we again and again give certain values to the numbers
that mark the sphere of gravitation. For the sake of simplification, I hear disregard the fact
that Einstein desires that also the way in which time is measured and represented by figures
shall have no influence upon the central value of the comparisons.
Whether this aim could be attained was a question of mathematical inquiry.
It really was attained, remarkably enough, and, we may say, to the surprise of Einstein himself,
although at the cost of considerable simplicity in the mathematical form,
it appeared necessary for the fixation of the field of gravitation in one or the other,
point in space to introduce no fewer than ten quantities in the place of the one that occurred
in the example mentioned above. In this connection, it is of importance to note that when we
exclude certain possibilities that would give rise to still greater intricacies, the form of
comparison used by Einstein to present the theory is the only possible one. The principle of the
freedom of choice in coordinates was the only one by which he needed to allow himself to be guided.
Although thus there was no special effort made to reach a connection with the theory of Newton,
it was evident, fortunately, at the end of the experiment that the connection existed.
If we avail ourselves of the simplifying circumstance that the velocities of the heavenly
bodies are slight in comparison with that of light, then we can deduce the theory of Newton
from the new theory, the universal relativity theory, as it is called by Einstein.
Thus, all the conclusions based upon the Newtonian theory hold good, as must naturally be required.
But now we have got further along. The Newtonian theory can no longer be regarded as absolutely
correct in all cases. There are slight deviations from it, which, although as a rule unnoticeable,
once in a while fall within the range of observation.
Now, there was a difficulty in the movement of the planet Mercury which could not be solved.
Even after all the disturbances caused by the attraction of other planets had been taken into
account, there remained an inexplicable phenomenon, that is, an extremely slow turning of
the ellipses described by Mercury on its own plane. Le Verrier had found that it amounted to
43 seconds a century. Einstein found that, according to his formulas, this movement must
really amount to just that much. Thus, with a single blow, he solved one of the greatest puzzles
of astronomy. Still more remarkable, because it has a bearing upon a phenomenon which
formerly could not be imagined, is the confirmation of Einstein's prediction regarding the
influence of gravitation upon the course of the rays of light. That such an influence must
exist is taught by a simple examination. We have only to turn back for a moment to the following
comparison in which we were just imagining ourselves to make our observations.
It was noted that when the compartment is falling with the acceleration of 981, the phenomena
therein will occur just as if there were no attraction of gravitation.
We can then see an object, A, stand still somewhere in open space.
A projectile, B, can travel with constant speed along a projectile.
horizontal line without varying from it in the slightest.
A ray of light can do the same.
Everybody will admit that in each case,
if there is no gravitation,
light will certainly extend itself in a rectilinear way.
If we limit the light to a flicker of the slightest duration
so that only a little bit C of a ray of light arises,
or if we fix our attention upon a sea,
single vibration of light, C, while we, on the other hand, give to the projectile B, a speed
equal to that of light, then we can conclude that B and C in their continued motion can
always remain next to each other. Now, if we watch all this, not from the movable compartment,
but from a place on the earth, then we shall note the usual falling movement of object A,
which shows us that we have to deal with a sphere of gravitation.
The projectile B will, in a bent path, vary more and more from a horizontal straight line,
and the light will do the same, because if we observe the movements from another standpoint,
this can have no effect upon the remaining next to each other of B and C.
End of Section 5.
Section 6 of The Einstein Theory of Relativity by Hendrik A. Lawrence.
This Librivox recording is in the public domain.
Recording by Hawaii in February 2020.
Deflection of Light
The bending of a ray of light thus described is much too light on the surface of the earth to be observed.
But the attraction of gravitation exercised by the sun on its sun.
surface is, because of its great mass, more than 27 times stronger, and a ray of light that
goes close by the superficies of the sun must truly be noticeably bent. The rays of a star
that are seen at a short distance from the edge of the sun will, going along the sun,
deviate so much from the original direction, that they strike the eye of an observer as if they
came in a straight line from a point somewhat further removed than the real position of the star
from the sun. It is at that point that we think we see the star, so here is a seeming displacement
from the sun, which increases in the measure in which the star is observed closer to the sun.
The Einstein theory teaches that the displacement is in inverse proportion to the apparent distance
of the star from the center of the sun, and that for a star just on its edge it will amount to
1.75 seconds. This is approximately the thousandth part of the apparent diameter of the sun.
Naturally, the phenomenon can only be observed when there is a total eclipse of the sun,
then one can take photographs of neighboring stars, and through comparing the plate with a picture of the same
part of the heavens, taken at a time when the sun was far removed from that point, the
sought for movement to one side may become apparent.
Thus, to put the Einstein theory to the test was the principal aim of the English expeditions
sent out to observe the eclipse of May 29th, one to Princess Island, off the coast of Guinea,
and the other to Sobral, Brazil.
The first-named Expeditions observers were Eddington and Cottingham,
those of the second, Cromelin and Davidson.
The conditions were especially favorable,
for a very large number of bright stars were shown on the photographic plate,
the observers at Sobral being particularly lucky in having good weather.
The total eclipse lasted five minutes,
during four of which it was perfectly clear,
so that good photographs could be taken.
In the report issued regarding the results,
the following figures,
which are the average of the measurements made from the seven plates,
are given for the displacement of seven stars.
1.02 seconds,
0.92 seconds,
0.84 seconds,
0.58 seconds,
0.54 seconds, 0.36 seconds, 0.34 seconds,
0.24 seconds.
Whereas, according to the theory,
the displacements should have amounted to 0.88 seconds,
0.80 seconds,
0.75 seconds, 0.40 seconds,
0.52 seconds, 0.33 seconds, 0.30 seconds, 0.20 seconds.
If we consider that, according to the theory,
the displacements must be in inverse ratio to the distance from the center of the sun,
then we may deduce from each observed displacement
how great the sideways movement for a star at the edge of the sun should have.
been. As the most probable result, therefore, the number 1.98 second was found from all the observations
together. As the last of the displacements given above, that is, 0.24 seconds, is about
one-eighth of this, we may say that the influence of the attraction of the sun upon light
made itself felt upon the ray at a distance eight times removed from its center.
The displacements calculated according to the theory are,
just because of the way in which they are calculated,
in inverse proportion to the distance to the center.
Now that the observed deviations also accord with the same rule,
it follows that they are surely proportionate with the calculated displacements.
The proportion of the first and the last observed sideways movements is 4.0,
and that of the two most extreme of the calculated numbers is 4.4.
This result is of importance, because thereby the theory is excluded,
or at least made extremely improbable,
that the phenomenon of refraction is to be ascribed to a ring of vapour surrounding the sun for a
great distance. Indeed, such a refraction should cause a deviation in the observed direction,
and, in order to produce the displacement of one of the stars under observation,
itself a slight proximity of the vapor ring should be sufficient. But we have every reason
to expect that if it were merely a question of a mass of gas around the sun, the diminishing
effect accompanying a removal from the sun should manifest itself much faster than is really the case.
We cannot speak with perfect certainty here, as all the factors that might be of influence upon
the distribution of density in a sun atmosphere are not well enough known, but we can surely
demonstrate that in case one of the gases with which we are acquainted were held in equilibrium,
solely by the influence of attraction of the sun,
the phenomenon should become much less
as soon as we got somewhat further
from the edge of the sun.
If the displacement of the first star,
which amounts to 1.02 seconds,
were to be ascribed to such a mass of gas,
then the displacement of the second
must already be entirely inappreciable.
So far,
as the absolute extent of the displacements is concerned,
it was found somewhat too great,
as has been shown by the figures given above.
It also appears from the final result
to be 1.98 for the edge of the sun,
that is, 13% greater than the theoretical value of 1.75.
It indeed seems that the discrepancies may be ascribed to faults in our own.
to faults in observations,
which supposition is supported
by the fact that the observations
at Princess Island,
which, it is true,
did not turn out quite as well
as those mentioned above,
gave the result of 1.64,
somewhat lower than Einstein's figure.
The observations made with a second instrument
that Sobral gave a result of
0.93,
but the observation
are of the opinion that because of the shifting of the mirror which reflected the race,
no value is to be attached to it.
End of Section 6.
Section 7 of the Einstein Theory of Relativity by Hendrik A. Lorenz.
This Librivox recording is in the public domain.
Recording by Hawaii in February 2020.
Difficulty exaggerated.
During a discussion of the results obtained at a joint meeting of the Royal Society
and the Royal Astronomical Society, held especially for that purpose recently in London,
it was the general opinion that Einstein's prediction might be regarded as justified,
and warm tributes to his genius were made on all sides.
Nevertheless, I cannot refrain, while I am mentioning it,
from expressing my surprise that, according to the report in the Times,
there should be so much complaint about the difficulty of understanding the new theory.
It is evident that Einstein's little book about the special and the general theory of relativity
in plain terms did not find its way into England during wartime.
Anyone reading it will, in my opinion, come to the conclusion that,
the basic ideas of the theory are really clear and simple. It is only to be regretted that it was
impossible to avoid clothing them in pretty involved mathematical terms, but we must not worry about that.
I allow myself to add that, as we follow Einstein, we may retain much of what has been
formally gained. The Newtonian theory remains in its full value as the first great step,
without which one cannot imagine the development of astronomy,
and without which the second step that has now been made
would hardly have been possible.
It remains, moreover, as the first,
and in most cases sufficient approximation.
It is true that, according to Einstein's theory,
because it leaves us entirely free
as to the way in which we wish to represent the phenomena,
we can imagine an idea of the solar system
in which the planets follow paths of peculiar form
and the rays of light shine along sharply bent lines,
think of a twisted and distorted planetarium.
But in every case where we apply it to concrete questions,
we shall so arrange it that the planets describe almost exact ellipses
and the rays of light almost straight lines.
It is not necessary to give up entirely even the ether.
Many natural philosophers find satisfaction in the idea of a material intermediate substance
in which the vibrations of light take place,
and they will very probably be all the more inclined to imagine such a medium
when they learn that, according to the Einstein theory,
gravitation itself does not spread instantaneously,
but with a velocity that at the first estimate may be compared with that of light.
Especially in former years where such interpretations current and repeated attempts were made
by speculations about the nature of the ether and about the mutations and movements
that might take place in it to arrive at a clear presentation of electromagnetic phenomena
and also of the functioning of gravitation.
In my opinion, it is not impossible
that in the future this road,
indeed abandoned at present,
will once more be followed with good results,
if only because it can lead to the thinking out
of new experimental tests.
Einstein's theory need not keep us from so doing,
only the ideas about the ether must accord with it.
Nevertheless, even without the color and clearness that the ether theories and the other models may be able to give,
and even we can feel it this way, just because of the soberness induced by their absence,
Einstein's work, we may now positively expect, will remain a monument of science.
His theory entirely fulfills the first and principal demand that we may make,
that of deducing the course of phenomena from certain principles exactly and to the smallest details it was certainly fortunate that he himself put the ether in the background
if he had not done so he probably would never have come upon the idea that has been the foundation of all his examinations thanks to his indefatigable exertions and perseverance for he had greater
difficulties to overcome in his attempts, Einstein has attained the results, which I have tried
to sketch, while still young. He is now 45 years old. He completed his first investigations
in Switzerland, where he first was engaged in the Patent Bureau at Bern, and later as a professor
at the Polytechnic in Zurich. After having been a professor for a short time at the University of Prague,
He settled in Berlin, where the Kaiser Wilhelm Institute afforded him the opportunity to devote himself exclusively to his scientific work.
He repeatedly visited our country and made his Netherlands colleagues, among whom he counts many good friends, partners in his studies and his results.
He attended the last meeting of the Department of Natural Philosophy of the Royal Academy of Sciences,
and the members then had the privilege of hearing him explain,
in his own fascinating, clear and simple way,
his interpretations of the fundamental questions
to which his theory gives rise.
End of Section 7.
End of the Einstein Theory of Relativity,
a concise statement by Hendrik A. Lawrence.
Thanks for listening.
