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Criticism of the theory of relativity

February 17, 2023

Criticism of the theory of relativity of Albert Einstein was mainly expressed in the early years after its publication in the early twentieth century, on scientific, pseudoscientific, philosophical, or ideological bases.[A 1][A 2][A 3] Though some of these criticisms had the support of reputable scientists, Einstein's theory of relativity is now accepted by the scientific community.[1]

Reasons for criticism of the theory of relativity have included alternative theories, rejection of the abstract-mathematical method, and alleged errors of the theory. According to some authors, antisemitic objections to Einstein's Jewish heritage also occasionally played a role in these objections.[A 1][A 2][A 3] There are still some critics of relativity today, but their opinions are not shared by the majority in the scientific community.[A 4][A 5]

Special relativity

Relativity principle versus electromagnetic worldview

Around the end of the 19th century, the view was widespread that all forces in nature are of electromagnetic origin (the "electromagnetic worldview"), especially in the works of Joseph Larmor (1897) and Wilhelm Wien (1900). This was apparently confirmed by the experiments of Walter Kaufmann (1901–1903), who measured an increase of the mass of a body with velocity which was consistent with the hypothesis that the mass was generated by its electromagnetic field. Max Abraham (1902) subsequently sketched a theoretical explanation of Kaufmann's result in which the electron was considered as rigid and spherical. However, it was found that this model was incompatible with the results of many experiments (including the Michelson–Morley experiment, the Experiments of Rayleigh and Brace, and the Trouton–Noble experiment), according to which no motion of an observer with respect to the luminiferous aether ("aether drift") had been observed despite numerous attempts to do so. Henri Poincaré (1902) conjectured that this failure arose from a general law of nature, which he called "the principle of relativity". Hendrik Antoon Lorentz (1904) created a detailed theory of electrodynamics (Lorentz ether theory) that was premised on the existence of an immobile aether and employed a set of space and time coordinate transformations that Poincaré called the Lorentz transformations, including the effects of length contraction and local time. However, Lorentz's theory only partially satisfied the relativity principle, because his transformation formulas for velocity and charge density were incorrect. This was corrected by Poincaré (1905) who obtained full Lorentz covariance of the electrodynamic equations.[A 6][B 1]

Criticizing Lorentz's 1904 theory, Abraham (1904) held that the Lorentz contraction of electrons requires a non-electromagnetic force to ensure the electron's stability. This was unacceptable to him as a proponent of the electromagnetic worldview. He continued that as long as a consistent explanation is missing as to how those forces and potentials act together on the electron, Lorentz's system of hypotheses is incomplete and doesn't satisfy the relativity principle.[A 7][C 1] Poincaré (1905) removed this objection by showing that the non-electromagnetic potential ("Poincaré stress") holding the electron together can be formulated in a Lorentz covariant way, and showed that in principle it is possible to create a Lorentz covariant model for gravitation which he considered non-electromagnetic in nature as well.[B 2] Thus the consistency of Lorentz's theory was proven, but the electromagnetic worldview had to be given up.[A 8][A 9] Eventually, Albert Einstein published in September 1905 what is now called special relativity, which was based on a radical new application of the relativity principle in connection with the constancy of the speed of light. In special relativity, the space and time coordinates depend on the inertial observer's frame of reference, and the luminiferous aether plays no role in the physics. Although this theory was founded on a very different kinematical model, it was experimentally indistinguishable from the aether theory of Lorentz and Poincaré, since both theories satisfy the relativity principle of Poincaré and Einstein, and both employ the Lorentz transformations. After Minkowski's introduction in 1908 of the geometric spacetime model for Einstein's version of relativity, most physicists eventually decided in favor of the Einstein-Minkowski version of relativity with its radical new views of space and time, in which there was no useful role for the aether.[B 3][A 8]

Claimed experimental refutations

Kaufmann–Bucherer–Neumann experiments: To conclusively decide between the theories of Abraham and Lorentz, Kaufmann repeated his experiments in 1905 with improved accuracy. However, in the meantime the theoretical situation had changed. Alfred Bucherer and Paul Langevin (1904) developed another model, in which the electron is contracted in the line of motion, and dilated in the transverse direction, so that the volume remains constant. While Kaufmann was still evaluating his experiments, Einstein published his theory of special relativity. Eventually, Kaufmann published his results in December 1905 and argued that they are in agreement with Abraham's theory and require rejection of the "basic assumption of Lorentz and Einstein" (the relativity principle). Lorentz reacted with the phrase "I am at the end of my Latin", while Einstein did not mention those experiments before 1908. Yet, others started to criticize the experiments. Max Planck (1906) alluded to inconsistencies in the theoretical interpretation of the data, and Adolf Bestelmeyer (1906) introduced new techniques, which (especially in the area of low velocities) gave different results and which cast doubts on Kaufmann's methods. Therefore, Bucherer (1908) conducted new experiments and arrived at the conclusion that they confirm the mass formula of relativity and thus the "relativity principle of Lorentz and Einstein". Yet Bucherer's experiments were criticized by Bestelmeyer leading to a sharp dispute between the two experimentalists. On the other hand, additional experiments of Hupka (1910), Neumann (1914) and others seemed to confirm Bucherer's result. The doubts lasted until 1940, when in similar experiments Abraham's theory was conclusively disproved. (It must be remarked that besides those experiments, the relativistic mass formula had already been confirmed by 1917 in the course of investigations on the theory of spectra. In modern particle accelerators, the relativistic mass formula is routinely confirmed.)[A 10][A 11][A 12][B 4][B 5][C 2]

In 1902–1906, Dayton Miller repeated the Michelson–Morley experiment together with Edward W. Morley. They confirmed the null result of the initial experiment. However, in 1921–1926, Miller conducted new experiments which apparently gave positive results.[C 3] Those experiments initially attracted some attention in the media and in the scientific community[A 13] but have been considered refuted for the following reasons:[A 14][A 15] Einstein, Max Born, and Robert S. Shankland pointed out that Miller had not appropriately considered the influence of temperature. A modern analysis by Roberts shows that Miller's experiment gives a null result, when the technical shortcomings of the apparatus and the error bars are properly considered.[B 6] Additionally, Miller's result is in disagreement with all other experiments, which were conducted before and after. For example, Georg Joos (1930) used an apparatus of similar dimensions to Miller's, but he obtained null results. In recent experiments of Michelson–Morley type where the coherence length is increased considerably by using lasers and masers the results are still negative.

In the 2011 Faster-than-light neutrino anomaly, the OPERA collaboration published results which appeared to show that the speed of neutrinos is slightly faster than the speed of light. However, sources of errors were found and confirmed in 2012 by the OPERA collaboration, which fully explained the initial results. In their final publication, a neutrino speed consistent with the speed of light was stated. Also subsequent experiments found agreement with the speed of light, see measurements of neutrino speed.[citation needed]

Acceleration in special relativity

It was also claimed that special relativity cannot handle acceleration, which would lead to contradictions in some situations. However, this assessment is not correct, since acceleration actually can be described in the framework of special relativity (see Acceleration (special relativity), Proper reference frame (flat spacetime), Hyperbolic motion, Rindler coordinates, Born coordinates). Paradoxes relying on insufficient understanding of these facts were discovered in the early years of relativity. For example, Max Born (1909) tried to combine the concept of rigid bodies with special relativity. That this model was insufficient was shown by Paul Ehrenfest (1909), who demonstrated that a rotating rigid body would, according to Born's definition, undergo a contraction of the circumference without contraction of the radius, which is impossible (Ehrenfest paradox). Max von Laue (1911) showed that rigid bodies cannot exist in special relativity, since the propagation of signals cannot exceed the speed of light, so an accelerating and rotating body will undergo deformations.[A 16][B 7][B 8][C 4]

Paul Langevin and von Laue showed that the twin paradox can be completely resolved by consideration of acceleration in special relativity. If two twins move away from each other, and one of them is accelerating and coming back to the other, then the accelerated twin is younger than the other one, since he was located in at least two inertial frames of reference, and therefore his assessment of which events are simultaneous changed during the acceleration. For the other twin nothing changes since he remained in a single frame.[A 17][B 9]

Another example is the Sagnac effect. Two signals were sent in opposite directions around a rotating platform. After their arrival a displacement of the interference fringes occurs. Sagnac himself believed that he had proved the existence of the aether. However, special relativity can easily explain this effect. When viewed from an inertial frame of reference, it is a simple consequence of the independence of the speed of light from the speed of the source, since the receiver runs away from one beam, while it approaches the other beam. When viewed from a rotating frame, the assessment of simultaneity changes during the rotation, and consequently the speed of light is not constant in accelerated frames.[A 18][B 10]

As was shown by Einstein, the only form of accelerated motion that cannot be non-locally described is the one due to gravitation. Einstein was also unsatisfied with the fact that inertial frames are preferred over accelerated frames. Thus over the course of several years (1908–1915), Einstein developed general relativity. This theory includes the replacement of Euclidean geometry by non-Euclidean geometry, and the resultant curvature of the path of light led Einstein (1912) to the conclusion that (like in extended accelerated frames) the speed of light is not constant in extended gravitational fields. Therefore, Abraham (1912) argued that Einstein had given special relativity a coup de grâce. Einstein responded that within its area of application (in areas where gravitational influences can be neglected) special relativity is still applicable with high precision, so one cannot speak of a coup de grâce at all.[A 19][B 11][B 12][B 13][C 5]

Superluminal speeds

In special relativity, the transfer of signals at superluminal speeds is impossible, since this would violate the Poincaré-Einstein synchronization, and the causality principle. Following an old argument by Pierre-Simon Laplace, Poincaré (1904) alluded to the fact that Newton's law of universal gravitation is founded on an infinitely great speed of gravity. So the clock-synchronization by light signals could in principle be replaced by a clock-synchronization by instantaneous gravitational signals. In 1905, Poincaré himself solved this problem by showing that in a relativistic theory of gravity the speed of gravity is equal to the speed of light. Although much more complicated, this is also the case in Einstein's theory of general relativity.[B 14][B 15][C 6]

Another apparent contradiction lies in the fact that the group velocity in anomalously dispersive media is higher than the speed of light. This was investigated by Arnold Sommerfeld (1907, 1914) and Léon Brillouin (1914). They came to the conclusion that in such cases the signal velocity is not equal to the group velocity, but to the front velocity which is never faster than the speed of light. Similarly, it is also argued that the apparent superluminal effects discovered by Günter Nimtz can be explained by a thorough consideration of the velocities involved.[A 20][B 16][B 17][B 18]

Also quantum entanglement (denoted by Einstein as "spooky action at a distance"), according to which the quantum state of one entangled particle cannot be fully described without describing the other particle, does not imply superluminal transmission of information (see quantum teleportation), and it is therefore in conformity with special relativity.[B 16]

Paradoxes

Insufficient knowledge of the basics of special relativity, especially the application of the Lorentz transformation in connection with length contraction and time dilation, led and still leads to the construction of various apparent paradoxes. Both the twin paradox and the Ehrenfest paradox and their explanation were already mentioned above. Besides the twin paradox, also the reciprocity of time dilation (i.e. every inertially moving observer considers the clock of the other one as being dilated) was heavily criticized by Herbert Dingle and others. For example, Dingle wrote a series of letters to Nature at the end of the 1950s. However, the self-consistency of the reciprocity of time dilation had already been demonstrated long before in an illustrative way by Lorentz (in his lectures from 1910, published 1931[A 21]) and many others—they alluded to the fact that it is only necessary to carefully consider the relevant measurement rules and the relativity of simultaneity. Other known paradoxes are the Ladder paradox and Bell's spaceship paradox, which also can simply be solved by consideration of the relativity of simultaneity.[A 22][A 23][C 7]

Aether and absolute space

Many physicists (like Hendrik Lorentz, Oliver Lodge, Albert Abraham Michelson, Edmund Taylor Whittaker, Harry Bateman, Ebenezer Cunningham, Charles Émile Picard, Paul Painlevé) were uncomfortable with the rejection of the aether, and preferred to interpret the Lorentz transformation based on the existence of a preferred frame of reference, as in the aether-based theories of Lorentz, Larmor, and Poincaré. However, the idea of an aether hidden from any observation was not supported by the mainstream scientific community, therefore the aether theory of Lorentz and Poincaré was superseded by Einstein's special relativity which was subsequently formulated in the framework of four-dimensional spacetime by Minkowski.[A 24][A 25][A 26][C 8][C 9][C 10]

Others such as Herbert E. Ives argued that it might be possible to experimentally determine the motion of such an aether,[C 11] but it was never found despite numerous experimental tests of Lorentz invariance (see tests of special relativity).

Also attempts to introduce some sort of relativistic aether (consistent with relativity) into modern physics such as by Einstein on the basis of general relativity (1920), or by Paul Dirac in relation to quantum mechanics (1951), were not supported by the scientific community (see Luminiferous aether#End of aether?).[A 27][B 19]

In his Nobel lecture, George F. Smoot (2006) described his own experiments on the Cosmic microwave background radiation anisotropy as "New Aether drift experiments". Smoot explained that "one problem to overcome was the strong prejudice of good scientists who learned the lesson of the Michelson and Morley experiment and Special Relativity that there were no preferred frames of reference." He continued that "there was an education job to convince them that this did not violate Special Relativity but did find a frame in which the expansion of the universe looked particularly simple."[B 20]

Alternative theories

The theory of complete aether drag, as proposed by George Gabriel Stokes (1844), was used by some critics as Ludwig Silberstein (1920) or Philipp Lenard (1920) as a counter-model of relativity. In this theory, the aether was completely dragged within and in the vicinity of matter, and it was believed that various phenomena, such as the absence of aether drift, could be explained in an "illustrative" way by this model. However, such theories are subject to great difficulties. Especially the aberration of light contradicted the theory, and all auxiliary hypotheses, which were invented to rescue it, are self-contradictory, extremely implausible, or in contradiction to other experiments like the Michelson–Gale–Pearson experiment. In summary, a sound mathematical and physical model of complete aether drag was never invented, consequently this theory was no serious alternative to relativity.[B 21][B 22][C 12][C 13]

Another alternative was the so-called emission theory of light. As in special relativity the aether concept is discarded, yet the main difference from relativity lies in the fact that the velocity of the light source is added to that of light in accordance with the Galilean transformation. As the hypothesis of complete aether drag, it can explain the negative outcome of all aether drift experiments. Yet, there are various experiments that contradict this theory. For example, the Sagnac effect is based on the independence of light speed from the source velocity, and the image of Double stars should be scrambled according to this model—which was not observed. Also in modern experiments in particle accelerators no such velocity dependence could be observed.[A 28][B 23][B 24][C 14] These results are further confirmed by the De Sitter double star experiment (1913), conclusively repeated in the X-ray spectrum by K. Brecher in 1977;[2] and the terrestrial experiment by Alväger, et al. (1963);,[3] which all show that the speed of light is independent of the motion of the source within the limits of experimental accuracy.

Principle of the constancy of the speed of light

Some consider the principle of the constancy of the velocity of light insufficiently substantiated. However, as already shown by Robert Daniel Carmichael (1910) and others, the constancy of the speed of light can be interpreted as a natural consequence of two experimentally demonstrated facts:[A 29][B 25]

  1. The velocity of light is independent of the velocity of the source, as demonstrated by De Sitter double star experiment, Sagnac effect, and many others (see emission theory).
  2. The velocity of light is independent of the direction of velocity of the observer, as demonstrated by Michelson–Morley experiment, Kennedy–Thorndike experiment, and many others (see luminiferous aether).

Note that measurements regarding the speed of light are actually measurements of the two-way speed of light, since the one-way speed of light depends on which convention is chosen to synchronize the clocks.

General relativity

General covariance

Einstein emphasized the importance of general covariance for the development of general relativity, and took the position that the general covariance of his 1915 theory of gravity ensured implementation of a generalized relativity principle. This view was challenged by Erich Kretschmann (1917), who argued that every theory of space and time (even including Newtonian dynamics) can be formulated in a covariant way, if additional parameters are included, and thus general covariance of a theory would in itself be insufficient to implement a generalized relativity principle. Although Einstein (1918) agreed with that argument, he also countered that Newtonian mechanics in general covariant form would be too complicated for practical uses. Although it is now understood that Einstein's response to Kretschmann was mistaken (subsequent papers showed that such a theory would still be usable), another argument can be made in favor of general covariance: it is a natural way to express the equivalence principle, i.e., the equivalence in the description of a free-falling observer and an observer at rest, and thus it is more convenient to use general covariance together with general relativity, rather than with Newtonian mechanics. Connected with this, also the question of absolute motion was dealt with. Einstein argued that the general covariance of his theory of gravity supports Mach's principle, which would eliminate any "absolute motion" within general relativity. However, as pointed out by Willem de Sitter in 1916, Mach's principle is not completely fulfilled in general relativity because there exist matter-free solutions of the field equations. This means that the "inertio-gravitational field", which describes both gravity and inertia, can exist in the absence of gravitating matter. However, as pointed out by Einstein, there is one fundamental difference between this concept and absolute space of Newton: the inertio-gravitational field of general relativity is determined by matter, thus it is not absolute.[A 30][A 31][B 26][B 27][B 28]

Bad Nauheim Debate

In the "Bad Nauheim Debate" (1920) between Einstein and (among others) Philipp Lenard, the latter stated the following objections: He criticized the lack of "illustrativeness" of Einstein's version of relativity, a condition that he suggested could only be met by an aether theory. Einstein responded that for physicists the content of "illustrativeness" or "common sense" had changed in time, so it could no longer be used as a criterion for the validity of a physical theory. Lenard also argued that with his relativistic theory of gravity Einstein had tacitly reintroduced the aether under the name "space". While this charge was rejected (among others) by Hermann Weyl, in an inaugural address given at the University of Leiden in 1920, shortly after the Bad Nauheim debates, Einstein himself acknowledged that according to his general theory of relativity, so-called "empty space" possesses physical properties that influence matter and vice versa. Lenard also argued that Einstein's general theory of relativity admits the existence of superluminal velocities, in contradiction to the principles of special relativity; for example, in a rotating coordinate system in which the Earth is at rest, the distant points of the whole universe are rotating around Earth with superluminal velocities. However, as Weyl pointed out, it is incorrect to handle a rotating extended system as a rigid body (neither in special nor in general relativity)—so the signal velocity of an object never exceeds the speed of light. Another criticism that was raised by both Lenard and Gustav Mie concerned the existence of "fictitious" gravitational fields in accelerating frames, which according to Einstein's Equivalence Principle are no less physically real than those produced by material sources. Lenard and Mie argued that physical forces can only be produced by real material sources, while the gravitational field that Einstein supposed to exist in an accelerating frame of reference has no concrete physical meaning. Einstein responded that, based on Mach's principle, one can think of these gravitational fields as induced by the distant masses. In this respect the criticism of Lenard and Mie has been vindicated, since according to the modern consensus, in agreement with Einstein's own mature views, Mach's principle as originally conceived by Einstein is not actually supported by general relativity, as already mentioned above.[A 32][C 15]

Silberstein–Einstein controversy

Ludwik Silberstein, who initially was a supporter of the special theory, objected at different occasions against general relativity. In 1920 he argued that the deflection of light by the sun, as observed by Arthur Eddington et al. (1919), is not necessarily a confirmation of general relativity, but may also be explained by the Stokes-Planck theory of complete aether drag. However, such models are in contradiction with the aberration of light and other experiments (see "Alternative theories"). In 1935, Silberstein claimed to have found a contradiction in the Two-body problem in general relativity. The claim was refuted by Einstein and Rosen (1935).[A 33][B 29][C 16]

Philosophical criticism

The consequences of relativity, such as the change of ordinary concepts of space and time, as well as the introduction of non-Euclidean geometry in general relativity, were criticized by some philosophers of different philosophical schools. Many philosophical critics had insufficient knowledge of the mathematical and formal basis of relativity,[A 34] which led to the criticisms often missing the heart of the matter. For example, relativity was misinterpreted as some form of relativism. However, this is misleading as it was emphasized by Einstein or Planck. On one hand it's true that space and time became relative, and the inertial frames of reference are handled on equal footing. On the other hand, the theory makes natural laws invariant—examples are the constancy of the speed of light, or the covariance of Maxwell's equations. Consequently, Felix Klein (1910) called it the "invariant theory of the Lorentz group" instead of relativity theory, and Einstein (who reportedly used expressions like "absolute theory") sympathized with this expression as well.[A 35][B 30][B 31][B 32]

Critical responses to relativity were also expressed by proponents of neo-Kantianism (Paul Natorp, Bruno Bauch etc.), and phenomenology (Oskar Becker, Moritz Geiger etc.). While some of them only rejected the philosophical consequences, others rejected also the physical consequences of the theory. Einstein was criticized for violating Immanuel Kant's categoric scheme, i.e., it was claimed that space-time curvature caused by matter and energy is impossible, since matter and energy already require the concepts of space and time. Also the three-dimensionality of space, Euclidean geometry, and the existence of absolute simultaneity were claimed to be necessary for the understanding of the world; none of them can possibly be altered by empirical findings. By moving all those concepts into a metaphysical area, any form of criticism of Kantianism would be prevented. Other pseudo-Kantians like Ernst Cassirer or Hans Reichenbach (1920), tried to modify Kant's philosophy. Subsequently, Reichenbach rejected Kantianism at all and became a proponent of logical positivism.[A 36][B 33][B 34][C 17][C 18][C 19]

Based on Henri Poincaré's conventionalism, philosophers such as Pierre Duhem (1914) and Hugo Dingler (1920) argued that the classical concepts of space, time, and geometry were, and will always be, the most convenient expressions in natural science, therefore the concepts of relativity cannot be correct. This was criticized by proponents of logical positivism such as Moritz Schlick, Rudolf Carnap, and Reichenbach. They argued that Poincaré's conventionalism could be modified to bring it into accord with relativity. Although it is true that the basic assumptions of Newtonian mechanics are simpler, it can only be brought into accord with modern experiments by inventing auxiliary hypotheses. On the other hand, relativity doesn't need such hypotheses, thus from a conceptual viewpoint, relativity is in fact simpler than Newtonian mechanics.[A 37][B 35][B 36][C 20]

Some proponents of Philosophy of Life, Vitalism, Critical realism (in German speaking countries) argued that there is a fundamental difference between physical, biological and psychological phenomena. For example, Henri Bergson (1921), who otherwise was a proponent of special relativity, argued that time dilation cannot be applied to biological organisms, therefore he denied the relativistic solution of the twin paradox. However, those claims were rejected by Paul Langevin, André Metz and others. Biological organisms consist of physical processes, so there is no reason to assume that they are not subject to relativistic effects like time dilation.[A 38][B 37][C 21]

Based on the philosophy of Fictionalism, the philosopher Oskar Kraus (1921) and others claimed that the foundations of relativity were only fictitious and even self-contradictory. Examples were the constancy of the speed of light, time dilation, length contraction. These effects appear to be mathematically consistent as a whole, but in reality they allegedly are not true. Yet, this view was immediately rejected. The foundations of relativity (such as the equivalence principle or the relativity principle) are not fictitious, but based on experimental results. Also, effects like constancy of the speed of light and relativity of simultaneity are not contradictory, but complementary to one another.[A 39][C 22]

In the Soviet Union (mostly in the 1920s), philosophical criticism was expressed on the basis of dialectic materialism. The theory of relativity was rejected as anti-materialistic and speculative, and a mechanistic worldview based on "common sense" was required as an alternative. Similar criticisms also occurred in the People's Republic of China during the Cultural Revolution. (On the other hand, other philosophers considered relativity as being compatible with Marxism.)[A 40][A 41]

Relativity hype and popular criticism

Although Planck already in 1909 compared the changes brought about by relativity with the Copernican Revolution, and although special relativity was accepted by most of the theoretical physicists and mathematicians by 1911, it was not before publication of the experimental results of the eclipse expeditions (1919) by a group around Arthur Stanley Eddington that relativity was noticed by the public. Following Eddington's publication of the eclipse results, Einstein was glowingly praised in the mass media, and was compared to Nikolaus Copernicus, Johannes Kepler and Isaac Newton, which caused a popular "relativity hype" ("Relativitätsrummel", as it was called by Sommerfeld, Einstein, and others). This triggered a counter-reaction of some scientists and scientific laymen who could not accept the concepts of modern physics, including relativity theory and quantum mechanics. The ensuing public controversy regarding the scientific status of Einstein's theory of gravity, which was unprecedented, was partly carried out in the press. Some of the criticism was not only directed to relativity, but personally at Einstein as well, who some of his critics accused of being behind the promotional campaign in the German press. [A 42][A 3]

Academic and non-academic criticism

Some academic scientists, especially experimental physicists such as the Nobel laureates Philipp Lenard and Johannes Stark, as well as Ernst Gehrcke, Stjepan Mohorovičić, Rudolf Tomaschek and others criticized the increasing abstraction and mathematization of modern physics, especially in the form of relativity theory, and later quantum mechanics. It was seen as a tendency to abstract theory building, connected with the loss of intuitive "common sense". In fact, relativity was the first theory, in which the inadequacy of the "illustrative" classical physics was thought to have been demonstrated. Some of Einstein's critics ignored these developments and tried to revitalize older theories, such as aether drag models or emission theories (see "Alternative Theories"). However, those qualitative models were never sufficiently advanced to compete with the success of the precise experimental predictions and explanatory powers of the modern theories. Additionally, there was also a great rivalry between experimental and theoretical physicists, as regards the professorial activities and the occupation of chairs at German universities. The opinions clashed at the "Bad Nauheim debates" in 1920 between Einstein and (among others) Lenard, which attracted much public attention.[A 43][A 42][C 15][C 23][C 24]

In addition, there were many critics (with or without physical training) whose ideas were far outside the scientific mainstream. These critics were mostly people who had developed their ideas long before the publication of Einstein's version of relativity, and they tried to resolve in a straightforward manner some or all of the enigmas of the world. Therefore, Wazeck (who studied some German examples) gave to these "free researchers" the name "world riddle solver" ("Welträtsellöser", such as Arvid Reuterdahl, Hermann Fricke or Johann Heinrich Ziegler). Their views had quite different roots in monism, Lebensreform, or occultism. Their views were typically characterized by the fact that they practically rejected the entire terminology and the (primarily mathematical) methods of modern science. Their works were published by private publishers, or in popular and non-specialist journals. It was significant for many "free researchers" (especially the monists) to explain all phenomena by intuitive and illustrative mechanical (or electrical) models, which also found its expression in their defense of the aether. For this reason they objected to the abstractness and inscrutability of the relativity theory, which was considered a pure calculation method that cannot reveal the true reasons underlying the phenomena. The "free researchers" often used Mechanical explanations of gravitation, in which gravity is caused by some sort of "aether pressure" or "mass pressure from a distance". Such models were regarded as an illustrative alternative to the abstract mathematical theories of gravitation of both Newton and Einstein. The enormous self-confidence of the "free researchers" is noteworthy, since they not only believed themselves to have solved the great riddles of the world, but many also seemed to expect that they would rapidly convince the scientific community.[A 44][C 25][C 26][C 27]

Since Einstein rarely defended himself against these attacks, this task was undertaken by other relativity theoreticians, who (according to Hentschel) formed some sort of "defensive belt" around Einstein. Some representatives were Max von Laue, Max Born, etc. and on popular-scientific and philosophical level Hans Reichenbach, André Metz etc., who led many discussions with critics in semi-popular journals and newspapers. However, most of these discussions failed from the start. Physicists like Gehrcke, some philosophers, and the "free researchers" were so obsessed with their own ideas and prejudices that they were unable to grasp the basics of relativity; consequently, the participants of the discussions were talking past each other. In fact, the theory that was criticized by them was not relativity at all, but rather a caricature of it. The "free researchers" were mostly ignored by the scientific community, but also, in time, respected physicists such as Lenard and Gehrcke found themselves in a position outside the scientific community. However, the critics didn't believe that this was due to their incorrect theories, but rather due to a conspiracy of the relativistic physicists (and in the 1920s and 1930s of the Jews as well), which allegedly tried to put down the critics, and to preserve and improve their own positions within the academic world. For example, Gehrcke (1920/24) held that the propagation of relativity is a product of some sort of mass suggestion. Therefore, he instructed a media monitoring service to collect over 5000 newspaper clippings which were related to relativity, and published his findings in a book. However, Gehrcke's claims were rejected, because the simple existence of the "relativity hype" says nothing about the validity of the theory, and thus it cannot be used for or against relativity.[A 45][A 46][C 28]

Afterward, some critics tried to improve their positions by the formation of alliances. One of them was the "Academy of Nations", which was founded in 1921 in the US by Robert T. Browne and Arvid Reuterdahl. Other members were Thomas Jefferson Jackson See and as well as Gehrcke and Mohorovičić in Germany. It is unknown whether other American critics such as Charles Lane Poor, Charles Francis Brush, Dayton Miller were also members. The alliance disappeared as early as the mid-1920s in Germany and by 1930 in the USA.[A 47]

Chauvinism and antisemitism

Main article: Deutsche Physik

Shortly before and during World War I, there appeared some nationalistically motivated criticisms of relativity and modern physics. For example, Pierre Duhem regarded relativity as the product of the "too formal and abstract" German spirit, which was in conflict with the "common sense". Similarly, popular criticism in the Soviet Union and China, which partly was politically organized, rejected the theory not because of factual objections, but as ideologically motivated as the product of western decadence.[A 48][A 40][A 41]

So in those countries, the Germans or the Western civilization were the enemies. However, in Germany the Jewish ancestry of some leading relativity proponents such as Einstein and Minkowski made them targets of racially minded critics, although many of Einstein's German critics did not show evidence of such motives. The engineer Paul Weyland, a known nationalistic agitator, arranged the first public meeting against relativity in Berlin in 1919. While Lenard and Stark were also known for their nationalistic opinions, they declined to participate in Weyland's rallies, and Weyland's campaign eventually fizzled out due to a lack of prominent speakers. Lenard and others instead responded to Einstein's challenge to his professional critics to debate his theories at the scientific conference held annually at Bad Nauheim. While Einstein's critics, assuming without any real justification that Einstein was behind the activities of the German press in promoting the triumph of relativity, generally avoided antisemitic attacks in their earlier publications, it later became clear to many observers that antisemitism did play a significant role in some of the attacks.[A 49]

Reacting to this underlying mood, Einstein himself openly speculated in a newspaper article that in addition to insufficient knowledge of theoretical physics, antisemitism at least partly motivated their criticisms. Some critics, including Weyland, reacted angrily and claimed that such accusations of antisemitism were only made to force the critics into silence. However, subsequently Weyland, Lenard, Stark and others clearly showed their antisemitic biases by beginning to combine their criticisms with racism. For example, Theodor Fritsch emphasized the alleged negative consequences of the "Jewish spirit" within relativity physics, and the far right-press continued this propaganda unhindered. After the murder of Walther Rathenau (1922) and murder threats against Einstein, he left Berlin for some time. Gehrcke's book on "The mass suggestion of relativity theory" (1924) was not antisemitic itself, but it was praised by the far-right press as describing an alleged typical Jewish behavior, which was also imputed to Einstein personally. Philipp Lenard in 1922 spoke about the "foreign spirit" as the foundation of relativity, and afterward he joined the Nazi party in 1924; Johannes Stark did the same in 1930. Both were proponents of the so-called German Physics, which only accepted scientific knowledge based on experiments, and only if accessible to the senses. According to Lenard (1936), this is the "Aryan physics or physics by man of Nordic kind" as opposed to the alleged formal-dogmatic "Jewish physics". Additional antisemitic critics can be found in the writings of Wilhelm Müller, Bruno Thüring and others. For example, Müller erroneously claimed that relativity was a purely "Jewish affair" and it would correspond to the "Jewish essence" etc., while Thüring made comparisons between the Talmud and relativity.[A 50][A 51][A 52][A 42][A 53][A 54][B 38][C 29][C 30][C 31]

Accusations of plagiarism and priority discussions

Some of Einstein's critics, like Lenard, Gehrcke and Reuterdahl, accused him of plagiarism, and questioned his priority claims to the authorship of relativity theory. The thrust of such allegations was to promote more traditional alternatives to Einstein's abstract hypothetico-deductive approach to physics, while Einstein himself was to be personally discredited. It was argued by Einstein's supporters that such personal accusations were unwarranted, since the physical content and the applicability of former theories were quite different from Einstein's theory of relativity. However, others argued that between them Poincaré and Lorentz had earlier published several of the core elements of Einstein's 1905 relativity paper, including a generalized relativity principle that was intended by Poincaré to apply to all physics. Some examples:[A 55][A 56][B 39][B 40][C 32][C 33]

  • Johann Georg von Soldner (1801) was credited for his calculation of the deflection of light in the vicinity of celestial bodies, long before Einstein's prediction which was based on general relativity. However, Soldner's derivation has nothing to do with Einstein's, since it was fully based on Newton's theory, and only gave half of the value as predicted by general relativity.
  • Paul Gerber (1898) published a formula for the perihelion advance of Mercury, which was formally identical to an approximate solution given by Einstein. However, since Einstein's formula was only an approximation, the solutions are not identical. In addition, Gerber's derivation has no connection with General relativity and was even regarded as meaningless.
  • Woldemar Voigt (1887) derived a transformation, which is very similar to the Lorentz transformation. As Voigt himself acknowledged, his theory was not based on electromagnetic theory, but on an elastic aether model. His transformation also violates the relativity principle.
  • Friedrich Hasenöhrl (1904) applied the concept of electromagnetic mass and momentum (which were known long before) to cavity radiation and thermal radiation. Yet, the applicability of Einstein's Mass–energy equivalence goes much further, since it is derived from the relativity principle and applies to all forms of energy.
  • Menyhért Palágyi (1901) developed a philosophical "space-time" model in which time plays the role of an imaginary fourth dimension. Palágyi's model was only a reformulation of Newtonian physics, and had no connection to electromagnetic theory, the relativity principle, or to the constancy of the speed of light.

Some contemporary historians of science have revived the question as to whether Einstein was possibly influenced by the ideas of Poincaré, who first stated the relativity principle and applied it to electrodynamics, developing interpretations and modifications of Lorentz's electron theory that appear to have anticipated what is now called special relativity. [A 57] Another discussion concerns a possible mutual influence between Einstein and David Hilbert as regards completing the field equations of general relativity (see Relativity priority dispute).

A Hundred Authors Against Einstein

A collection of various criticisms can be found in the book Hundert Autoren gegen Einstein (A Hundred Authors Against Einstein), published in 1931.[4] It contains very short texts from 28 authors, and excerpts from the publications of another 19 authors. The rest consists of a list that also includes people who only for some time were opposed to relativity. From among Einstein's concepts the most targeted one is space-time followed by the speed of light as a constant and the relativity of simultaneity, with other concepts following.[5] Besides philosophic objections (mostly based on Kantianism), also some alleged elementary failures of the theory were included; however, as some commented, those failures were due to the authors' misunderstanding of relativity. For example, Hans Reichenbach wrote a report in the entertainment section of a newspaper, describing the book as “a magnificent collection of naive mistakes” and as “unintended droll literature.”[A 58][6] Albert von Brunn interpreted the book as a pamphlet "of such deplorable impotence as occurring elsewhere only in politics" and "a fallback into the 16th and 17th centuries" and concluded “it can only be hoped that German science will not again be embarrassed by such sad scribblings”,[A 58] and Einstein said, in response to the book, that if he were wrong, then one author would have been enough.[7][8]

According to Goenner, the contributions to the book are a mixture of mathematical–physical incompetence, hubris, and the feelings of the critics of being suppressed by contemporary physicists advocating the new theory. The compilation of the authors show, Goenner continues, that this was not a reaction within the physics community—only one physicist (Karl Strehl) and three mathematicians (Jean-Marie Le Roux, Emanuel Lasker and Hjalmar Mellin) were present—but a reaction of an inadequately educated academic citizenship, which did not know what to do with relativity. As regards the average age of the authors: 57% were substantially older than Einstein, one third was around the same age, and only two persons were substantially younger.[A 59] Two authors (Reuterdahl, von Mitis) were antisemitic and four others were possibly connected to the Nazi movement. On the other hand, no antisemitic expression can be found in the book, and it also included contributions of some authors of Jewish ancestry (Salomo Friedländer, Ludwig Goldschmidt, Hans Israel, Emanuel Lasker, Oskar Kraus, Menyhért Palágyi).[A 59][A 60][C 34]

Status of criticism

See also: Tests of special relativity and Tests of general relativity

The theory of relativity is considered to be self-consistent, is consistent with many experimental results, and serves as the basis of many successful theories like quantum electrodynamics. Therefore, fundamental criticism (like that of Herbert Dingle, Louis Essen, Petr Beckmann, Maurice Allais and Tom van Flandern) has not been taken seriously by the scientific community, and due to the lack of quality of many critical publications (found in the process of peer review) they were rarely accepted for publication in reputable scientific journals. Just as in the 1920s, most critical works are published in small publication houses, alternative journals (like "Apeiron" or "Galilean Electrodynamics"), or private websites.[A 4][A 5] Consequently, where criticism of relativity has been dealt with by the scientific community, it has mostly been in historical studies.[A 1][A 2][A 3]

However, this does not mean that there is no further development in modern physics. The progress of technology over time has led to extremely precise ways of testing the predictions of relativity, and so far it has successfully passed all tests (such as in particle accelerators to test special relativity, and by astronomical observations to test general relativity). In addition, in the theoretical field there is continuing research intended to unite general relativity and quantum theory, between which a fundamental incompatibility still remains.[9] The most promising models are string theory and loop quantum gravity. Some variations of those models also predict violations of Lorentz invariance on a very small scale.[B 41][B 42][B 43]

See also

References

  1. ^ Pruzan, Peter (2016). Research Methodology: The Aims, Practices and Ethics of Science (illustrated ed.). Springer. p. 81. ISBN 978-3-319-27167-5. Extract of page 81
  2. ^ Brecher, K. (1977), "Is the speed of light independent of the velocity of the source", Physical Review Letters, 39 (17): 1051–1054, Bibcode:1977PhRvL..39.1051B, doi:10.1103/PhysRevLett.39.1051, S2CID 26217047.
  3. ^ Alväger, T.; Nilsson, A.; Kjellman, J. (1963), "A Direct Terrestrial Test of the Second Postulate of Special Relativity", Nature, 197 (4873): 1191, Bibcode:1963Natur.197.1191A, doi:10.1038/1971191a0, S2CID 4190242
  4. ^ Israel, Hans; Ruckhaber, Erich; Weinmann, Rudolf, eds. (1931). Hundert Autoren gegen Einstein. Leipzig: Voigtländer.
  5. ^ Cuntz, Manfred (November–December 2020). . Skeptical Inquirer. Amherst, New York: Center for Inquiry. Archived from the original on 25 August 2021. Retrieved 25 August 2021.
  6. ^ Maria Reichenbach; R. S. Cohen (1978). Hans Reichenbach Selected Writings 1909–1953. D. Reidel Publishing Company. pp. 273–274. doi:10.1007/978-94-009-9761-5_31.
  7. ^ Russo, Remigio (1996). Mathematical Problems in Elasticity, Vol 18. World Scientific. p. 125. ISBN 978-981-02-2576-6. Extract of page 125
  8. ^ Hawking, Stephen (1998). A brief history of time (10th ed.). Bantam Books. p. 193. ISBN 978-0-553-38016-3.
  9. ^ Sachs, Mendel (2013). Quantum Mechanics and Gravity. Springer Science & Business Media. p. 148. ISBN 978-3-662-09640-6. Extract of page 148

Historical analyses

  1. ^ a b c Hentschel (1990)
  2. ^ a b c Goenner (1993ab)
  3. ^ a b c d Wazeck (2009)
  4. ^ a b Farrell (2007)
  5. ^ a b Wazeck (2010)
  6. ^ Miller (1981), pp. 47–75
  7. ^ Miller (1981), pp. 75–85
  8. ^ a b Darrigol (2000), pp. 372–392
  9. ^ Janssen (2007), pp. 25–34
  10. ^ Pauli (1921), pp. 636–637
  11. ^ Pauli (1981), pp. 334–352
  12. ^ Staley (2009), pp. 219–259
  13. ^ Lalli (2012), pp. 171–186
  14. ^ Swenson (1970), pp. 63–68
  15. ^ Lalli (2012), pp. 187–212.
  16. ^ Pauli (1920), pp. 689–691
  17. ^ Laue (1921a), pp. 59, 75–76
  18. ^ Laue (1921a), pp. 25–26, 128–130
  19. ^ Pais (1982), pp. 177–207, 230–232
  20. ^ Pauli (1921), 672–673
  21. ^ Miller (1981), pp. 257–264
  22. ^ Chang (1993)
  23. ^ Mathpages: Dingle
  24. ^ Miller (1983), pp. 216–217
  25. ^ Warwick (2003), pp. 410–419, 469–475
  26. ^ Paty (1987), pp. 145–147
  27. ^ Kragh (1990), pp. 189–205
  28. ^ Norton (2004), pp. 14–22
  29. ^ Hentschel (1990), pp. 343–348.
  30. ^ Janssen (2008), pp. 3–4, 17–18, 28–38
  31. ^ Norton (1993)
  32. ^ Goenner (1993a), pp. 124–128
  33. ^ Havas (1993), pp. 97–120
  34. ^ Hentschel (1990), Chapter 6.2, pp. 555–557
  35. ^ Hentschel (1990), pp. 92–105, 401–419
  36. ^ Hentschel (1990), pp. 199–239, 254–268, 507–526
  37. ^ Hentschel (1990), pp. 293–336
  38. ^ Hentschel (1990), pp. 240–243, 441–455
  39. ^ Hentschel (1990), pp. 276–292
  40. ^ a b Vizgin/Gorelik (1987), pp. 265–326
  41. ^ a b Hu (2007), 549–555
  42. ^ a b c Goenner (1993a)
  43. ^ Hentschel (1990), pp. 74–91
  44. ^ Wazeck (2009), pp. 27–84
  45. ^ Hentschel (1990), pp. 163–195
  46. ^ Wazeck (2009), pp. 113–193, 217–292
  47. ^ Wazeck (2009), pp. 293–378
  48. ^ Hentschel (1990), pp. 123–131
  49. ^ Wazeck (2009), pp. 232–236
  50. ^ Kleinert (1979)
  51. ^ Beyerchen (1982)
  52. ^ Hentschel (1990), pp. 131–150
  53. ^ Posch (2006)
  54. ^ Wazeck (2009), pp. 271–392
  55. ^ Hentschel (1990), pp. 150–162
  56. ^ Wazeck (2009), pp. 194–216
  57. ^ Darrigol (2004)
  58. ^ a b Goenner (1993b), p. 251.
  59. ^ a b Goenner (1993b)
  60. ^ Wazeck (2009), pp. 356–361
  • Beyerchen, Alan D. (1977). Scientists under Hitler. New Haven: Yale University Press. ISBN 978-0-300-01830-1.
  • Chang, Hasok (1993). "A misunderstood rebellion: The twin-paradox controversy and Herbert Dingle's vision of science". Studies in History and Philosophy of Science Part A. 24 (5): 741–790. Bibcode:1993SHPSA..24..741C. doi:10.1016/0039-3681(93)90063-P.
  • Darrigol, Olivier (2004). "The Mystery of the Einstein-Poincaré Connection". Isis. 95 (4): 614–626. Bibcode:2004Isis...95..614D. doi:10.1086/430652. PMID 16011297. S2CID 26997100.
  • Goenner, Hubert (1993a). "The reaction to relativity theory I: the Anti-Einstein campaign in Germany in 1920". Science in Context. 6: 107–133. doi:10.1017/S0269889700001332. S2CID 123551958.
  • Goenner, Hubert (1993b). "The reaction to relativity theory in Germany III. Hundred Authors against Einstein". In Earman, John; Janssen, Michel; Norton, John D. (eds.). The Attraction of Gravitation (Einstein Studies). Vol. 5. Boston—Basel: Birkhäuser. pp. 248–273. ISBN 978-0-8176-3624-1.
  • Havas, P. (1993). "The General-Relativistic Two-Body Problem and the Einstein-Silberstein Controversy". In Earman, John; Janssen, Michel; Norton, John D. (eds.). The Attraction of Gravitation (Einstein Studies). Vol. 5. Boston—Basel: Birkhäuser. pp. 88–122. ISBN 978-0-8176-3624-1.
  • John Farrell (2007). . COSMOS Magazine (11). Archived from the original on 11 August 2014. Retrieved 23 November 2013.
  • Hentschel, Klaus (1990). Interpretationen und Fehlinterpretationen der speziellen und der allgemeinen Relativitätstheorie durch Zeitgenossen Albert Einsteins. Basel—Boston—Bonn: Birkhäuser. doi:10.18419/opus-7182. ISBN 978-3-7643-2438-4.
  • Hentschel, Klaus (1996). Physics and national socialism: an anthology of primary sources. Basel—Boston—Bonn: Birkhäuser. ISBN 978-3-7643-5312-4.
  • Hu, Danian (2007). "The Reception of Relativity in China". Isis. 98 (3): 539–557. doi:10.1086/521157. PMID 17970426. S2CID 34243229.
  • Janssen, Michel; Mecklenburg, Matthew (2007). "From classical to relativistic mechanics: Electromagnetic models of the electron". In V. F. Hendricks; et al. (eds.). Interactions: Mathematics, Physics and Philosophy. Dordrecht: Springer. pp. 65–134.
  • Janssen, Michel (2014). "'No Success like Failure ...': Einstein's Quest for General Relativity, 1907–1920". In Michel Janssen; Christoph Lehner (eds.). The Cambridge Companion to Einstein. Vol. 1. Cambridge University Press. p. 167. doi:10.1017/CCO9781139024525.008. ISBN 978-0521828345..
  • Darrigol, Olivier (2000). Electrodynamics from Ampére to Einstein. Oxford: Clarendon Press. ISBN 978-0-19-850594-5.
  • Kleinert, Andreas (1979). "Nationalistische und antisemitische Ressentiments von Wissenschaftlern gegen Einstein". Einstein Symposion Berlin. Einstein-Symposion Berlin. Lecture Notes in Physics. Vol. 100. pp. 501–516. Bibcode:1979LNP...100..501K. doi:10.1007/3-540-09718-X_91. ISBN 978-3-540-09718-1.
  • Kragh, Helge (2005). Dirac. A Scientific Biography. Cambridge: Cambridge University Press. ISBN 978-0-521-01756-5.
  • Lalli, Roberto (2012). "The Reception of Miller's Ether-Drift Experiments in the USA: The History of a Controversy in Relativity Revolution". Annals of Science. 69 (2): 153–214. doi:10.1080/00033790.2011.637473. S2CID 143410980.
  • Mathpages: Herbert Dingle and the Twins; What Happened to Dingle?
  • Miller, Arthur I. (1981). Albert Einstein's special theory of relativity. Emergence (1905) and early interpretation (1905–1911). Reading: Addison–Wesley. ISBN 978-0-201-04679-3.
  • Norton, John D. (1993). "General Covariance and the Foundations of General Relativity: Eight Decades of Dispute" (PDF). Reports on Progress in Physics. 56 (7): 791–858. Bibcode:1993RPPh...56..791N. doi:10.1088/0034-4885/56/7/001. S2CID 250902085.
  • Norton, John D. (2004). "Einstein's Investigations of Galilean Covariant Electrodynamics prior to 1905". Archive for History of Exact Sciences. 59 (1): 45–105. Bibcode:2004AHES...59...45N. doi:10.1007/s00407-004-0085-6. S2CID 17459755.
  • Pais, Abraham (2000) [1982]. Subtle Is the Lord. Oxford: Oxford University Press. ISBN 978-0-19-280672-7.
  • Paty, Michel (1987). "The scientific reception of relativity in France". In Glick, T.F. (ed.). The Comparative Reception of Relativity. Dordrecht: Kluwer Academic Publishers. pp. 113–168. ISBN 978-90-277-2498-4.
  • Pauli, Wolfgang (1921), "Die Relativitätstheorie", Encyclopädie der Mathematischen Wissenschaften, 5 (2): 539–776
In English: Pauli, W. (1981) [1921]. Theory of Relativity. Fundamental Theories of Physics. Vol. 165. ISBN 978-0-486-64152-2.
  • Posch, Th.; Kerschbaum, F.; Lackner, K. (2006). "Bruno Thürings Umsturzversuch der Relativitätstheorie" (PDF). In Gudrun Wolfschmidt (ed.). Nuncius Hamburgensis—Beiträge zur Geschichte der Naturwissenschaften. Vol. 4.
  • Staley, Richard (2009). Einstein's generation. The origins of the relativity revolution. Chicago: University of Chicago Press. ISBN 978-0-226-77057-4.
  • Swenson, Loyd S. (1970). "The Michelson-Morley-Miller Experiments before and after 1905". Journal for the History of Astronomy. 1: 56–78. Bibcode:1970JHA.....1...56S. doi:10.1177/002182867000100108. S2CID 125905904.
  • Vizgin, V. P.; Gorelik G. E. (1987). "The Reception of the Theory of Relativity in Russia and the USSR". In Glick, T.F. (ed.). The Comparative Reception of Relativity. Dordrecht: Kluwer Academic Publishers. pp. 265–326. ISBN 978-90-277-2498-4.
  • Warwick, Andrew (2003). Masters of Theory: Cambridge and the Rise of Mathematical Physics. Chicago: University of Chicago Press. ISBN 978-0-226-87375-6.
  • Wazeck, Milena (2009). Einsteins Gegner: Die öffentliche Kontroverse um die Relativitätstheorie in den 1920er Jahren. Frankfurt—New York: Campus. ISBN 978-3-593-38914-1.
  • English translation: Wazeck, Milena (2013). Einstein's Opponents: The Public Controversy about the Theory of Relativity in the 1920s. Translated by Geoffrey S. Koby. Cambridge University Press. ISBN 978-1-107-01744-3.
  • Wazeck, Milena (2010). "Einstein's sceptics: Who were the relativity deniers?". New Scientist (2786).
  • Zahar, Elie (2001). Poincaré's Philosophy: From Conventionalism to Phenomenology. Chicago: Open Court Pub Co. ISBN 978-0-8126-9435-2.
  • Zeilinger, Anton (2005). Einsteins Schleier: Die neue Welt der Quantenphysik. München: Goldmann. ISBN 978-3-442-15302-2.

Relativity papers

  1. ^ Lorentz (1904)
  2. ^ Poincaré (1906)
  3. ^ Einstein (1905)
  4. ^ Planck (1906b)
  5. ^ Bucherer (1908)
  6. ^ Roberts (2006)
  7. ^ Born (1909)
  8. ^ Laue (1911)
  9. ^ Langevin (1911)
  10. ^ Langevin (1921)
  11. ^ Einstein (1908)
  12. ^ Einstein (1912)
  13. ^ Einstein (1916)
  14. ^ Poincaré (1906)
  15. ^ Carlip (1999)
  16. ^ a b PhysicsFaq: FTL
  17. ^ Sommerfeld (1907, 1914)
  18. ^ Brillouin (1914)
  19. ^ Dirac (1951)
  20. ^ Smoot (2006), pp. 123–124
  21. ^ Joos (1959), pp. 448ff
  22. ^ Michelson (1925)
  23. ^ De Sitter (1913)
  24. ^ Fox (1965)
  25. ^ Carmichael (1910)
  26. ^ De Sitter (1916ab)
  27. ^ Kretschmann (1917)
  28. ^ Einstein (1920, 1924)
  29. ^ Einstein/Rosen (1936)
  30. ^ Klein (1910)
  31. ^ Petzoldt (1921)
  32. ^ Planck (1925)
  33. ^ Reichenbach (1920)
  34. ^ Cassirer (1921)
  35. ^ Schlick (1921)
  36. ^ Reichenbach (1924)
  37. ^ Metz (1923)
  38. ^ Einstein (1920a)
  39. ^ Laue (1917)
  40. ^ Laue (1921b)
  41. ^ Mattingly (2005)
  42. ^ Will (2006)
  43. ^ Liberati (2009)
  • Born, Max (1909). "Die Theorie des starren Körpers in der Kinematik des Relativitätsprinzips". Annalen der Physik. 335 (11): 1–56. Bibcode:1909AnP...335....1B. doi:10.1002/andp.19093351102.
  • Brillouin, Léon (1914). "Über die Fortpflanzung des Lichtes in dispergierenden Medien". Annalen der Physik. 349 (10): 203–240. Bibcode:1914AnP...349..203B. doi:10.1002/andp.19143491003.
  • Bucherer, A. H. (1908), "Messungen an Becquerelstrahlen. Die experimentelle Bestätigung der Lorentz-Einsteinschen Theorie. (Measurements of Becquerel rays. The Experimental Confirmation of the Lorentz-Einstein Theory)", Physikalische Zeitschrift, 9 (22): 755–762
  • Carlip, Steve (2000). "Aberration and the Speed of Gravity". Physics Letters A. 267 (2–3): 81–87. arXiv:gr-qc/9909087. Bibcode:2000PhLA..267...81C. doi:10.1016/S0375-9601(00)00101-8. S2CID 12941280.
  • Carmichael, R. D. (1910). "On the Theory of Relativity: Analysis of the Postulates" . Physical Review. 35 (3): 153–176. Bibcode:1912PhRvI..35..153C. doi:10.1103/physrevseriesi.35.153.
  • Cassirer, Ernst (1923). Substance and function, and Einstein's theory of relativity. Chicago; London: The Open court publishing company.
  • De Sitter, Willem (1913), "A proof of the constancy of the velocity of light" , Proceedings of the Royal Netherlands Academy of Arts and Sciences, 15 (2): 1297–1298, Bibcode:1913KNAB...15.1297D
  • De Sitter, Willem (1916a). "On the relativity of rotation in Einstein's theory". Roy. Amst. Proc. 17 (1): 527–532.[permanent dead link]
  • De Sitter, Willem (1916b). "On the relativity of inertia. Remarks concerning Einstein's latest hypothesis". Roy. Amst. Proc. 17 (2): 1217–1225. Bibcode:1917KNAB...19.1217D.[permanent dead link].
  • Dirac, Paul (1951). (PDF). Nature. 168 (4282): 906–907. Bibcode:1951Natur.168..906D. doi:10.1038/168906a0. S2CID 4288946. Archived from the original (PDF) on 17 December 2008. Retrieved 31 January 2011..
  • Einstein, Albert (1905a), "Zur Elektrodynamik bewegter Körper" (PDF), Annalen der Physik, 322 (10): 891–921, Bibcode:1905AnP...322..891E, doi:10.1002/andp.19053221004, hdl:10915/2786. See also: English translation.
  • Einstein, Albert (1908), "Über das Relativitätsprinzip und die aus demselben gezogenen Folgerungen" (PDF), Jahrbuch der Radioaktivität und Elektronik, 4: 411–462, Bibcode:1908JRE.....4..411E
  • Einstein, Albert (1912). "Relativität und Gravitation. Erwiderung auf eine Bemerkung von M. Abraham" (PDF). Annalen der Physik. 343 (10): 1059–1064. Bibcode:1912AnP...343.1059E. doi:10.1002/andp.19123431014. S2CID 120162895.
  • Einstein, Albert (1916). "Die Grundlage der allgemeinen Relativitätstheorie" (PDF). Annalen der Physik. 49 (7): 769–782. Bibcode:1916AnP...354..769E. doi:10.1002/andp.19163540702. hdl:2027/wu.89059241638.
  • Einstein, A. (1920a). . Berliner Tageblatt. 402. Archived from the original on 14 December 2009.
  • Einstein, Albert (1920b). Ether and the Theory of Relativity . London: Methuen. pp. 3–24.
  • Einstein, Albert (1924). "Über den Äther". Verhandlungen der Schweizerischen Naturforschenden Gesellschaft. 105: 85–93..
  • Einstein, Albert; Rosen, Nathan (1936). "Two-Body Problem in General Relativity". Physical Review. 49 (5): 404–405. Bibcode:1936PhRv...49..404E. doi:10.1103/PhysRev.49.404.2.
  • Fox, J. G. (1965). "Evidence Against Emission Theories". American Journal of Physics. 33 (1): 1–17. Bibcode:1965AmJPh..33....1F. doi:10.1119/1.1971219.
  • Joos, Georg (1959). Lehrbuch der theoretischen Physik. Frankfurt am Main: Akademische Verlagsgesellschaft, Frankfurt. p. 448.
  • Kretschmann, Erich (1917). "Uber den physikalischen Sinn der Relativitätspostulate. A. Einsteins neue und seine ursprüngliche Relativitätstheorie". Annalen der Physik. 358 (16): 575–614. Bibcode:1918AnP...358..575K. doi:10.1002/andp.19183581602.
  • Langevin, P. (1911). Translated by J. B. Sykes in 1973. "The evolution of space and time". Scientia. X: 31–54.
  • Langevin, Paul (1921). "Sur la théorie de relativité et l'expérience de M. Sagnac". Comptes Rendus. 173: 831–834.
  • Langevin, Paul (1937). "Sur l'expérience de Sagnac". Comptes Rendus. 205: 304–306.
  • Laue, Max von (1911), "Zur Diskussion über den starren Körper in der Relativitätstheorie" [On the Discussion Concerning Rigid Bodies in the Theory of Relativity], Physikalische Zeitschrift, 12: 85–87
  • Laue, Max von (1917). "Die Fortpflanzungsgeschwindigkeit der Gravitation. Bemerkungen zur gleichnamigen Abhandlung von P. Gerber". Annalen der Physik. 358 (11): 214–216. Bibcode:1917AnP...358..214V. doi:10.1002/andp.19173581103.
  • Laue, Max von (1921a). Die Relativitätstheorie. Vol. 1. Braunschweig: Friedr. Vieweg & Sohn..
  • Laue, Max von (1921b). "Erwiderung auf Hrn. Lenards Vorbemerkungen zur Soldnerschen Arbeit von 1801". Annalen der Physik. 371 (20): 283–284. Bibcode:1921AnP...371..283L. doi:10.1002/andp.19213712005.
  • Liberati, Stefano; Maccione, Luca (2009). "Lorentz Violation: Motivation and new constraints". Annual Review of Nuclear and Particle Science. 59 (1): 245–267. arXiv:0906.0681. Bibcode:2009ARNPS..59..245L. doi:10.1146/annurev.nucl.010909.083640. S2CID 7495956.
  • Lorentz, Hendrik Antoon (1904). "Electromagnetic phenomena in a system moving with any velocity smaller than that of light" . Proceedings of the Royal Netherlands Academy of Arts and Sciences. 6: 809–831. Bibcode:1903KNAB....6..809L.
  • Mattingly, David (2005). "Modern Tests of Lorentz Invariance". Living Reviews in Relativity. 8 (5): 5. arXiv:gr-qc/0502097. Bibcode:2005LRR.....8....5M. doi:10.12942/lrr-2005-5. PMC 5253993. PMID 28163649.
  • Metz, André (1923). La Relativité. Paris: Chiron.
  • Michelson, A. A.; Gale, Henry G. (1925). "The Effect of the Earth's Rotation on the Velocity of Light, II". Astrophysical Journal. 61: 140. Bibcode:1925ApJ....61..140M. doi:10.1086/142879..
  • Planck, Max (1906a), "Das Prinzip der Relativität und die Grundgleichungen der Mechanik" [The Principle of Relativity and the Fundamental Equations of Mechanics], Verhandlungen Deutsche Physikalische Gesellschaft, 8: 136–141
  • Planck, Max (1906b), "Die Kaufmannschen Messungen der Ablenkbarkeit der β-Strahlen in ihrer Bedeutung für die Dynamik der Elektronen" [The Measurements of Kaufmann on the Deflectability of β-Rays in their Importance for the Dynamics of the Electrons], Physikalische Zeitschrift, 7: 753–761
  • Planck, Max (1925). "Vom Relativen zum Absoluten". Naturwissenschaften. 13 (3): 52–59. Bibcode:1925NW.....13...53P. doi:10.1007/BF01559357. S2CID 19895936.
  • Poincaré, Henri (1906), "Sur la dynamique de l'électron"  [On the Dynamics of the Electron], Rendiconti del Circolo Matematico di Palermo, 21: 129–176, Bibcode:1906RCMP...21..129P, doi:10.1007/BF03013466, hdl:2027/uiug.30112063899089, S2CID 120211823
  • Reichenbach, Hans (1965) [First published in German 1920]. The theory of relativity and a priori knowledge. Berkeley: University of California Press.
  • Reichenbach, Hans (1969) [First published in German 1924]. Axiomatization of the theory of relativity. Berkeley: University of California Press.
  • Roberts, Thomas J.: An Explanation of Dayton Miller's Anomalous "Ether Drift" Result, 2006, arXiv:physics/0608238
  • Schlick, Moritz (1921). Space and time in contemporary physics (3. ed.). New York: Oxford University Press.
  • Smoot, G. F.; (2006), Nobel lecture: Cosmic Microwave Background Radiation Anisotropies: Their Discovery and Utilization
  • Sommerfeld, Arnold (1907). "Ein Einwand gegen die Relativtheorie der Elektrodynamik und seine Beseitigung" [An Objection Against the Theory of Relativity and its Removal]. Physikalische Zeitschrift. 8 (23): 841–842.
  • Sommerfeld, Arnold (1914). "Über die Fortpflanzung des Lichtes in dispergierenden Medien". Annalen der Physik. 349 (10): 177–202. Bibcode:1914AnP...349..177S. doi:10.1002/andp.19143491002.
  • Usenet Physics FAQ: is FTL travel or communication Possible?
  • Will, Clifford M. (2006). "The Confrontation between General Relativity and Experiment". Living Reviews in Relativity. 9 (3): 3. arXiv:gr-qc/0510072. Bibcode:2006LRR.....9....3W. doi:10.12942/lrr-2006-3. PMC 5256066. PMID 28179873.

Critical works

  1. ^ Abraham (1904)
  2. ^ Kaufmann (1906)
  3. ^ Miller (1933)
  4. ^ Ehrenfest (1909)
  5. ^ Abraham (1912)
  6. ^ Poincaré (1904)
  7. ^ Dingle (1972)
  8. ^ Lodge (1925)
  9. ^ Michelson (1927)
  10. ^ Prokhovnik (1963)
  11. ^ Ives (1951)
  12. ^ Lenard (1921a)
  13. ^ Silberstein (1921a)
  14. ^ Ritz (1908)
  15. ^ a b Lenard, Einstein, Gehrcke, Weyl (1920)
  16. ^ Silberstein (1936)
  17. ^ Natorp (1910)
  18. ^ Linke (1921)
  19. ^ Friedlaender (1932)
  20. ^ Dingler (1922)
  21. ^ Bergson (1921)
  22. ^ Kraus (1921)
  23. ^ Gehrcke (1924a)
  24. ^ Mohorovičić (1923)
  25. ^ Fricke (1919)
  26. ^ Ziegler (1920)
  27. ^ Reuterdahl (1921)
  28. ^ Gehrcke (1924b)
  29. ^ Lenard (1936)
  30. ^ Stark/Müller (1941)
  31. ^ Thüring (1941)
  32. ^ Gehrcke (1916)
  33. ^ Lenard (1921b)
  34. ^ Israel et al. (1931)
  • Abraham, Max (1904). "Die Grundhypothesen der Elektronentheorie" [The Fundamental Hypotheses of the Theory of Electrons]. Physikalische Zeitschrift. 5: 576–579.
  • Abraham, Max, Max (1912). "Relativität und Gravitation. Erwiderung auf eine Bemerkung des Herrn A. Einstein". Annalen der Physik. 343 (10): 1056–1058. Bibcode:1912AnP...343.1056A. doi:10.1002/andp.19123431013.
  • Bergson, Henri (1923) [First edition 1921]. Durée et simultanéité. A propos de la théorie d'Einstein (second ed.). Saint-Germain: Félix Alcan.
  • Dingle, Herbert (1972). Science at the Crossroads. London: Martin Brian & O'Keeffe. ISBN 978-0-85616-060-8.
  • Dingler, Hugo (1922). Relativitätstheorie und Ökonomieprinzip. Leipzig: S. Hirzel.
  • Ehrenfest, Paul (1909), "Gleichförmige Rotation starrer Körper und Relativitätstheorie"  [Uniform Rotation of Rigid Bodies and the Theory of Relativity], Physikalische Zeitschrift, 10: 918, Bibcode:1909PhyZ...10..918E
  • Essen, Louis (1971). The Special Theory of Relativity: A Critical Analysis. Oxford: Oxford University Press. ISBN 978-0-19-851921-8.
  • Fricke, Hermann (1919). Der Fehler in Einsteins Relativitätstheorie. Wolfenbüttel: Heckner.
  • Friedlaender, Salomo (2005) [1932]. "Kant gegen Einstein". In Geerken, Hartmut; Thiel, Detlef (eds.). Gesammelte Schriften. Books on Demand. ISBN 978-3-8370-0052-8.
  • Gehrcke, Ernst (1916). "Zur Kritik und Geschichte der neueren Gravitationstheorien". Annalen der Physik. 356 (17): 119–124. Bibcode:1916AnP...356..119G. doi:10.1002/andp.19163561704.
  • Gehrcke, Ernst (1924a). Kritik der Relativitätstheorie : Gesammelte Schriften über absolute und relative Bewegung. Berlin: Meusser.
  • Gehrcke, Ernst (1924b). Die Massensuggestion der Relativitätstheorie: Kulturhistorisch-psychologische Dokumente. Berlin: Meuser.
  • Ives, Herbert E. (1951). "Revisions of the Lorentz transformation". Proceedings of the American Philosophical Society. 95 (2): 125–131.
  • Kaufmann, Walter (1906), "Über die Konstitution des Elektrons" [On the Constitution of the Electron], Annalen der Physik, 324 (3): 487–553, Bibcode:1906AnP...324..487K, doi:10.1002/andp.19063240303
  • Kraus, Oskar (1921). "Fiktion und Hypothese in der Einsteinschen Relativitätstheorie. Erkenntnistheoretische Betrachtungen". Annalen der Philosophie. 2 (3): 335–396. doi:10.1007/BF02903489. S2CID 169705566.
  • Lenard, Philipp (1921a) [1920]. Über Relativitätsprinzip, Äther, Gravitation (3. enlarged ed.). Leipzig: Hirzel.
  • Lenard; Einstein; Gehrcke; Weyl (1920). "The Bad Nauheim Debate" . Physikalische Zeitschrift. 21: 666–668.
  • Lenard, Philipp. (Hrsg.) (1921b). "Vorbemerkung zu Soldners "Über die Ablenkung eines Lichtstrahls von seiner geradlinigen Bewegung durch die Attraktion eines Weltkörpers, an welchem er nahe vorbeigeht";". Annalen der Physik. 370 (15): 593–604. Bibcode:1921AnP...370..593S. doi:10.1002/andp.19213701503.
  • Lenard, Philipp (1936). Deutsche Physik. Vol. 1. München: J.F. Lehmann.
  • Linke, Paul F. (1921). "Relativitätstheorie und Relativismus. Betrachtungen über Relativitätstheorie, Logik und Phänomenologie". Annalen der Philosophie. 2 (3): 397–438. doi:10.1007/BF02903490. S2CID 127977740.
  • Lodge, Oliver (2003) [1925]. Ether and Reality. Whitefish: Kessinger. ISBN 978-0-7661-7865-6.
  • Michelson, Albert A. (1927). Studies in Optics. Chicago: University Press. p. 155.
  • Miller, Dayton C. (1933). "The Ether-Drift Experiment and the Determination of the Absolute Motion of the Earth". Reviews of Modern Physics. 5 (3): 203–242. Bibcode:1933RvMP....5..203M. doi:10.1103/RevModPhys.5.203. S2CID 4119615.
  • Mohorovičić, Stjepan (1923). Die Einsteinsche Relativitätstheorie und ihr mathematischer, physikalischer und philosophischer Charakter. Berlin: de Gruyter.
  • Natorp, Paul (1910). "Das Relativitätsprinzip etc.". Die logischen Grundlagen der exakten Wissenschaften. Leipzig & Berlin: B.G. Teubner. pp. 392–404.
  • Poincaré, Henri (1913) [1904]. "The Principles of Mathematical Physics" . The Value of Science (Chap. 7–9). New York: Science Press. pp. 297–320.. (This paper is only partly to be considered as critical, since the question after the validity of the relativity principle remained undecided. It was Poincaré himself, who solved many problems in 1905.)
  • Prokhovnik, Simon Jacques (1963). "The Case for an Aether". The British Journal for the Philosophy of Science. 14 (55): 195–207. doi:10.1093/bjps/XIV.55.195. S2CID 122050844.
  • Reuterdahl, Arvid (1920). Scientific theism versus materialism. The space-time potential. New York: Devin-Adair.
  • Ritz, Walter (1908). "Recherches critiques sur l'Électrodynamique Générale". Annales de Chimie et de Physique. 13: 145–275. Bibcode:1908AChPh..13..145R. Siehe auch .
  • Silberstein, Ludwik (1920). "The Recent Eclipse Results and Stokes-Planck's Æther". Philosophical Magazine. 6. 39 (230): 162–171.
  • Silberstein, Ludwik (1936). "Two-Centers Solution of the Gravitational Field Equations, and the Need for a Reformed Theory of Matter". Physical Review. 49 (3): 268–270. Bibcode:1936PhRv...49..268S. doi:10.1103/PhysRev.49.268.
  • Stark, Johannes; Müller, Wilhelm (1941). "Jüdische und Deutsche Physik". Vorträge an der Universität München.
  • Thüring, Bruno (1941). "Albert Einsteins Umsturzversuch der Physik und seine inneren Möglichkeiten und Ursachen". Forschungen zur Judenfrage. 4: 134–162.
  • Ziegler, Johann Heinrich (1857–1936 ) (1920). "Das Ding an sich" und das Ende der sog. Relativitätstheorie. Zürich: Weltformel-Verlag.

External links

  • The Newspaper clippings and works collected by Gehrcke and Reuterdahl form an important basis for historic research on the criticism of relativity;
    • The Ernst Gehrcke Papers. Over 2700 newspaper articles collected by Gehrcke, digitized at the MPIWG.
    • , digizied by the University of St. Thomas Libraries, which are online accessible.

February 17, 2023
criticism, theory, relativity, this, article, unclear, citation, style, references, used, made, clearer, with, different, consistent, style, citation, footnoting, july, 2016, learn, when, remove, this, template, message, albert, einstein, mainly, expressed, ea. This article has an unclear citation style The references used may be made clearer with a different or consistent style of citation and footnoting July 2016 Learn how and when to remove this template message Criticism of the theory of relativity of Albert Einstein was mainly expressed in the early years after its publication in the early twentieth century on scientific pseudoscientific philosophical or ideological bases A 1 A 2 A 3 Though some of these criticisms had the support of reputable scientists Einstein s theory of relativity is now accepted by the scientific community 1 Reasons for criticism of the theory of relativity have included alternative theories rejection of the abstract mathematical method and alleged errors of the theory According to some authors antisemitic objections to Einstein s Jewish heritage also occasionally played a role in these objections A 1 A 2 A 3 There are still some critics of relativity today but their opinions are not shared by the majority in the scientific community A 4 A 5 Contents 1 Special relativity 1 1 Relativity principle versus electromagnetic worldview 1 2 Claimed experimental refutations 1 3 Acceleration in special relativity 1 4 Superluminal speeds 1 5 Paradoxes 1 6 Aether and absolute space 1 7 Alternative theories 1 8 Principle of the constancy of the speed of light 2 General relativity 2 1 General covariance 2 2 Bad Nauheim Debate 2 3 Silberstein Einstein controversy 3 Philosophical criticism 4 Relativity hype and popular criticism 4 1 Academic and non academic criticism 4 2 Chauvinism and antisemitism 4 3 Accusations of plagiarism and priority discussions 4 4 A Hundred Authors Against Einstein 5 Status of criticism 6 See also 7 References 7 1 Historical analyses 7 2 Relativity papers 7 3 Critical works 8 External linksSpecial relativity EditRelativity principle versus electromagnetic worldview Edit Around the end of the 19th century the view was widespread that all forces in nature are of electromagnetic origin the electromagnetic worldview especially in the works of Joseph Larmor 1897 and Wilhelm Wien 1900 This was apparently confirmed by the experiments of Walter Kaufmann 1901 1903 who measured an increase of the mass of a body with velocity which was consistent with the hypothesis that the mass was generated by its electromagnetic field Max Abraham 1902 subsequently sketched a theoretical explanation of Kaufmann s result in which the electron was considered as rigid and spherical However it was found that this model was incompatible with the results of many experiments including the Michelson Morley experiment the Experiments of Rayleigh and Brace and the Trouton Noble experiment according to which no motion of an observer with respect to the luminiferous aether aether drift had been observed despite numerous attempts to do so Henri Poincare 1902 conjectured that this failure arose from a general law of nature which he called the principle of relativity Hendrik Antoon Lorentz 1904 created a detailed theory of electrodynamics Lorentz ether theory that was premised on the existence of an immobile aether and employed a set of space and time coordinate transformations that Poincare called the Lorentz transformations including the effects of length contraction and local time However Lorentz s theory only partially satisfied the relativity principle because his transformation formulas for velocity and charge density were incorrect This was corrected by Poincare 1905 who obtained full Lorentz covariance of the electrodynamic equations A 6 B 1 Criticizing Lorentz s 1904 theory Abraham 1904 held that the Lorentz contraction of electrons requires a non electromagnetic force to ensure the electron s stability This was unacceptable to him as a proponent of the electromagnetic worldview He continued that as long as a consistent explanation is missing as to how those forces and potentials act together on the electron Lorentz s system of hypotheses is incomplete and doesn t satisfy the relativity principle A 7 C 1 Poincare 1905 removed this objection by showing that the non electromagnetic potential Poincare stress holding the electron together can be formulated in a Lorentz covariant way and showed that in principle it is possible to create a Lorentz covariant model for gravitation which he considered non electromagnetic in nature as well B 2 Thus the consistency of Lorentz s theory was proven but the electromagnetic worldview had to be given up A 8 A 9 Eventually Albert Einstein published in September 1905 what is now called special relativity which was based on a radical new application of the relativity principle in connection with the constancy of the speed of light In special relativity the space and time coordinates depend on the inertial observer s frame of reference and the luminiferous aether plays no role in the physics Although this theory was founded on a very different kinematical model it was experimentally indistinguishable from the aether theory of Lorentz and Poincare since both theories satisfy the relativity principle of Poincare and Einstein and both employ the Lorentz transformations After Minkowski s introduction in 1908 of the geometric spacetime model for Einstein s version of relativity most physicists eventually decided in favor of the Einstein Minkowski version of relativity with its radical new views of space and time in which there was no useful role for the aether B 3 A 8 Claimed experimental refutations Edit Kaufmann Bucherer Neumann experiments To conclusively decide between the theories of Abraham and Lorentz Kaufmann repeated his experiments in 1905 with improved accuracy However in the meantime the theoretical situation had changed Alfred Bucherer and Paul Langevin 1904 developed another model in which the electron is contracted in the line of motion and dilated in the transverse direction so that the volume remains constant While Kaufmann was still evaluating his experiments Einstein published his theory of special relativity Eventually Kaufmann published his results in December 1905 and argued that they are in agreement with Abraham s theory and require rejection of the basic assumption of Lorentz and Einstein the relativity principle Lorentz reacted with the phrase I am at the end of my Latin while Einstein did not mention those experiments before 1908 Yet others started to criticize the experiments Max Planck 1906 alluded to inconsistencies in the theoretical interpretation of the data and Adolf Bestelmeyer 1906 introduced new techniques which especially in the area of low velocities gave different results and which cast doubts on Kaufmann s methods Therefore Bucherer 1908 conducted new experiments and arrived at the conclusion that they confirm the mass formula of relativity and thus the relativity principle of Lorentz and Einstein Yet Bucherer s experiments were criticized by Bestelmeyer leading to a sharp dispute between the two experimentalists On the other hand additional experiments of Hupka 1910 Neumann 1914 and others seemed to confirm Bucherer s result The doubts lasted until 1940 when in similar experiments Abraham s theory was conclusively disproved It must be remarked that besides those experiments the relativistic mass formula had already been confirmed by 1917 in the course of investigations on the theory of spectra In modern particle accelerators the relativistic mass formula is routinely confirmed A 10 A 11 A 12 B 4 B 5 C 2 In 1902 1906 Dayton Miller repeated the Michelson Morley experiment together with Edward W Morley They confirmed the null result of the initial experiment However in 1921 1926 Miller conducted new experiments which apparently gave positive results C 3 Those experiments initially attracted some attention in the media and in the scientific community A 13 but have been considered refuted for the following reasons A 14 A 15 Einstein Max Born and Robert S Shankland pointed out that Miller had not appropriately considered the influence of temperature A modern analysis by Roberts shows that Miller s experiment gives a null result when the technical shortcomings of the apparatus and the error bars are properly considered B 6 Additionally Miller s result is in disagreement with all other experiments which were conducted before and after For example Georg Joos 1930 used an apparatus of similar dimensions to Miller s but he obtained null results In recent experiments of Michelson Morley type where the coherence length is increased considerably by using lasers and masers the results are still negative In the 2011 Faster than light neutrino anomaly the OPERA collaboration published results which appeared to show that the speed of neutrinos is slightly faster than the speed of light However sources of errors were found and confirmed in 2012 by the OPERA collaboration which fully explained the initial results In their final publication a neutrino speed consistent with the speed of light was stated Also subsequent experiments found agreement with the speed of light see measurements of neutrino speed citation needed Acceleration in special relativity Edit It was also claimed that special relativity cannot handle acceleration which would lead to contradictions in some situations However this assessment is not correct since acceleration actually can be described in the framework of special relativity see Acceleration special relativity Proper reference frame flat spacetime Hyperbolic motion Rindler coordinates Born coordinates Paradoxes relying on insufficient understanding of these facts were discovered in the early years of relativity For example Max Born 1909 tried to combine the concept of rigid bodies with special relativity That this model was insufficient was shown by Paul Ehrenfest 1909 who demonstrated that a rotating rigid body would according to Born s definition undergo a contraction of the circumference without contraction of the radius which is impossible Ehrenfest paradox Max von Laue 1911 showed that rigid bodies cannot exist in special relativity since the propagation of signals cannot exceed the speed of light so an accelerating and rotating body will undergo deformations A 16 B 7 B 8 C 4 Paul Langevin and von Laue showed that the twin paradox can be completely resolved by consideration of acceleration in special relativity If two twins move away from each other and one of them is accelerating and coming back to the other then the accelerated twin is younger than the other one since he was located in at least two inertial frames of reference and therefore his assessment of which events are simultaneous changed during the acceleration For the other twin nothing changes since he remained in a single frame A 17 B 9 Another example is the Sagnac effect Two signals were sent in opposite directions around a rotating platform After their arrival a displacement of the interference fringes occurs Sagnac himself believed that he had proved the existence of the aether However special relativity can easily explain this effect When viewed from an inertial frame of reference it is a simple consequence of the independence of the speed of light from the speed of the source since the receiver runs away from one beam while it approaches the other beam When viewed from a rotating frame the assessment of simultaneity changes during the rotation and consequently the speed of light is not constant in accelerated frames A 18 B 10 As was shown by Einstein the only form of accelerated motion that cannot be non locally described is the one due to gravitation Einstein was also unsatisfied with the fact that inertial frames are preferred over accelerated frames Thus over the course of several years 1908 1915 Einstein developed general relativity This theory includes the replacement of Euclidean geometry by non Euclidean geometry and the resultant curvature of the path of light led Einstein 1912 to the conclusion that like in extended accelerated frames the speed of light is not constant in extended gravitational fields Therefore Abraham 1912 argued that Einstein had given special relativity a coup de grace Einstein responded that within its area of application in areas where gravitational influences can be neglected special relativity is still applicable with high precision so one cannot speak of a coup de grace at all A 19 B 11 B 12 B 13 C 5 Superluminal speeds Edit In special relativity the transfer of signals at superluminal speeds is impossible since this would violate the Poincare Einstein synchronization and the causality principle Following an old argument by Pierre Simon Laplace Poincare 1904 alluded to the fact that Newton s law of universal gravitation is founded on an infinitely great speed of gravity So the clock synchronization by light signals could in principle be replaced by a clock synchronization by instantaneous gravitational signals In 1905 Poincare himself solved this problem by showing that in a relativistic theory of gravity the speed of gravity is equal to the speed of light Although much more complicated this is also the case in Einstein s theory of general relativity B 14 B 15 C 6 Another apparent contradiction lies in the fact that the group velocity in anomalously dispersive media is higher than the speed of light This was investigated by Arnold Sommerfeld 1907 1914 and Leon Brillouin 1914 They came to the conclusion that in such cases the signal velocity is not equal to the group velocity but to the front velocity which is never faster than the speed of light Similarly it is also argued that the apparent superluminal effects discovered by Gunter Nimtz can be explained by a thorough consideration of the velocities involved A 20 B 16 B 17 B 18 Also quantum entanglement denoted by Einstein as spooky action at a distance according to which the quantum state of one entangled particle cannot be fully described without describing the other particle does not imply superluminal transmission of information see quantum teleportation and it is therefore in conformity with special relativity B 16 Paradoxes Edit Insufficient knowledge of the basics of special relativity especially the application of the Lorentz transformation in connection with length contraction and time dilation led and still leads to the construction of various apparent paradoxes Both the twin paradox and the Ehrenfest paradox and their explanation were already mentioned above Besides the twin paradox also the reciprocity of time dilation i e every inertially moving observer considers the clock of the other one as being dilated was heavily criticized by Herbert Dingle and others For example Dingle wrote a series of letters to Nature at the end of the 1950s However the self consistency of the reciprocity of time dilation had already been demonstrated long before in an illustrative way by Lorentz in his lectures from 1910 published 1931 A 21 and many others they alluded to the fact that it is only necessary to carefully consider the relevant measurement rules and the relativity of simultaneity Other known paradoxes are the Ladder paradox and Bell s spaceship paradox which also can simply be solved by consideration of the relativity of simultaneity A 22 A 23 C 7 Aether and absolute space Edit Many physicists like Hendrik Lorentz Oliver Lodge Albert Abraham Michelson Edmund Taylor Whittaker Harry Bateman Ebenezer Cunningham Charles Emile Picard Paul Painleve were uncomfortable with the rejection of the aether and preferred to interpret the Lorentz transformation based on the existence of a preferred frame of reference as in the aether based theories of Lorentz Larmor and Poincare However the idea of an aether hidden from any observation was not supported by the mainstream scientific community therefore the aether theory of Lorentz and Poincare was superseded by Einstein s special relativity which was subsequently formulated in the framework of four dimensional spacetime by Minkowski A 24 A 25 A 26 C 8 C 9 C 10 Others such as Herbert E Ives argued that it might be possible to experimentally determine the motion of such an aether C 11 but it was never found despite numerous experimental tests of Lorentz invariance see tests of special relativity Also attempts to introduce some sort of relativistic aether consistent with relativity into modern physics such as by Einstein on the basis of general relativity 1920 or by Paul Dirac in relation to quantum mechanics 1951 were not supported by the scientific community see Luminiferous aether End of aether A 27 B 19 In his Nobel lecture George F Smoot 2006 described his own experiments on the Cosmic microwave background radiation anisotropy as New Aether drift experiments Smoot explained that one problem to overcome was the strong prejudice of good scientists who learned the lesson of the Michelson and Morley experiment and Special Relativity that there were no preferred frames of reference He continued that there was an education job to convince them that this did not violate Special Relativity but did find a frame in which the expansion of the universe looked particularly simple B 20 Alternative theories Edit The theory of complete aether drag as proposed by George Gabriel Stokes 1844 was used by some critics as Ludwig Silberstein 1920 or Philipp Lenard 1920 as a counter model of relativity In this theory the aether was completely dragged within and in the vicinity of matter and it was believed that various phenomena such as the absence of aether drift could be explained in an illustrative way by this model However such theories are subject to great difficulties Especially the aberration of light contradicted the theory and all auxiliary hypotheses which were invented to rescue it are self contradictory extremely implausible or in contradiction to other experiments like the Michelson Gale Pearson experiment In summary a sound mathematical and physical model of complete aether drag was never invented consequently this theory was no serious alternative to relativity B 21 B 22 C 12 C 13 Another alternative was the so called emission theory of light As in special relativity the aether concept is discarded yet the main difference from relativity lies in the fact that the velocity of the light source is added to that of light in accordance with the Galilean transformation As the hypothesis of complete aether drag it can explain the negative outcome of all aether drift experiments Yet there are various experiments that contradict this theory For example the Sagnac effect is based on the independence of light speed from the source velocity and the image of Double stars should be scrambled according to this model which was not observed Also in modern experiments in particle accelerators no such velocity dependence could be observed A 28 B 23 B 24 C 14 These results are further confirmed by the De Sitter double star experiment 1913 conclusively repeated in the X ray spectrum by K Brecher in 1977 2 and the terrestrial experiment by Alvager et al 1963 3 which all show that the speed of light is independent of the motion of the source within the limits of experimental accuracy Principle of the constancy of the speed of light Edit Some consider the principle of the constancy of the velocity of light insufficiently substantiated However as already shown by Robert Daniel Carmichael 1910 and others the constancy of the speed of light can be interpreted as a natural consequence of two experimentally demonstrated facts A 29 B 25 The velocity of light is independent of the velocity of the source as demonstrated by De Sitter double star experiment Sagnac effect and many others see emission theory The velocity of light is independent of the direction of velocity of the observer as demonstrated by Michelson Morley experiment Kennedy Thorndike experiment and many others see luminiferous aether Note that measurements regarding the speed of light are actually measurements of the two way speed of light since the one way speed of light depends on which convention is chosen to synchronize the clocks General relativity EditGeneral covariance Edit Einstein emphasized the importance of general covariance for the development of general relativity and took the position that the general covariance of his 1915 theory of gravity ensured implementation of a generalized relativity principle This view was challenged by Erich Kretschmann 1917 who argued that every theory of space and time even including Newtonian dynamics can be formulated in a covariant way if additional parameters are included and thus general covariance of a theory would in itself be insufficient to implement a generalized relativity principle Although Einstein 1918 agreed with that argument he also countered that Newtonian mechanics in general covariant form would be too complicated for practical uses Although it is now understood that Einstein s response to Kretschmann was mistaken subsequent papers showed that such a theory would still be usable another argument can be made in favor of general covariance it is a natural way to express the equivalence principle i e the equivalence in the description of a free falling observer and an observer at rest and thus it is more convenient to use general covariance together with general relativity rather than with Newtonian mechanics Connected with this also the question of absolute motion was dealt with Einstein argued that the general covariance of his theory of gravity supports Mach s principle which would eliminate any absolute motion within general relativity However as pointed out by Willem de Sitter in 1916 Mach s principle is not completely fulfilled in general relativity because there exist matter free solutions of the field equations This means that the inertio gravitational field which describes both gravity and inertia can exist in the absence of gravitating matter However as pointed out by Einstein there is one fundamental difference between this concept and absolute space of Newton the inertio gravitational field of general relativity is determined by matter thus it is not absolute A 30 A 31 B 26 B 27 B 28 Bad Nauheim Debate Edit In the Bad Nauheim Debate 1920 between Einstein and among others Philipp Lenard the latter stated the following objections He criticized the lack of illustrativeness of Einstein s version of relativity a condition that he suggested could only be met by an aether theory Einstein responded that for physicists the content of illustrativeness or common sense had changed in time so it could no longer be used as a criterion for the validity of a physical theory Lenard also argued that with his relativistic theory of gravity Einstein had tacitly reintroduced the aether under the name space While this charge was rejected among others by Hermann Weyl in an inaugural address given at the University of Leiden in 1920 shortly after the Bad Nauheim debates Einstein himself acknowledged that according to his general theory of relativity so called empty space possesses physical properties that influence matter and vice versa Lenard also argued that Einstein s general theory of relativity admits the existence of superluminal velocities in contradiction to the principles of special relativity for example in a rotating coordinate system in which the Earth is at rest the distant points of the whole universe are rotating around Earth with superluminal velocities However as Weyl pointed out it is incorrect to handle a rotating extended system as a rigid body neither in special nor in general relativity so the signal velocity of an object never exceeds the speed of light Another criticism that was raised by both Lenard and Gustav Mie concerned the existence of fictitious gravitational fields in accelerating frames which according to Einstein s Equivalence Principle are no less physically real than those produced by material sources Lenard and Mie argued that physical forces can only be produced by real material sources while the gravitational field that Einstein supposed to exist in an accelerating frame of reference has no concrete physical meaning Einstein responded that based on Mach s principle one can think of these gravitational fields as induced by the distant masses In this respect the criticism of Lenard and Mie has been vindicated since according to the modern consensus in agreement with Einstein s own mature views Mach s principle as originally conceived by Einstein is not actually supported by general relativity as already mentioned above A 32 C 15 Silberstein Einstein controversy Edit Ludwik Silberstein who initially was a supporter of the special theory objected at different occasions against general relativity In 1920 he argued that the deflection of light by the sun as observed by Arthur Eddington et al 1919 is not necessarily a confirmation of general relativity but may also be explained by the Stokes Planck theory of complete aether drag However such models are in contradiction with the aberration of light and other experiments see Alternative theories In 1935 Silberstein claimed to have found a contradiction in the Two body problem in general relativity The claim was refuted by Einstein and Rosen 1935 A 33 B 29 C 16 Philosophical criticism EditThe consequences of relativity such as the change of ordinary concepts of space and time as well as the introduction of non Euclidean geometry in general relativity were criticized by some philosophers of different philosophical schools Many philosophical critics had insufficient knowledge of the mathematical and formal basis of relativity A 34 which led to the criticisms often missing the heart of the matter For example relativity was misinterpreted as some form of relativism However this is misleading as it was emphasized by Einstein or Planck On one hand it s true that space and time became relative and the inertial frames of reference are handled on equal footing On the other hand the theory makes natural laws invariant examples are the constancy of the speed of light or the covariance of Maxwell s equations Consequently Felix Klein 1910 called it the invariant theory of the Lorentz group instead of relativity theory and Einstein who reportedly used expressions like absolute theory sympathized with this expression as well A 35 B 30 B 31 B 32 Critical responses to relativity were also expressed by proponents of neo Kantianism Paul Natorp Bruno Bauch etc and phenomenology Oskar Becker Moritz Geiger etc While some of them only rejected the philosophical consequences others rejected also the physical consequences of the theory Einstein was criticized for violating Immanuel Kant s categoric scheme i e it was claimed that space time curvature caused by matter and energy is impossible since matter and energy already require the concepts of space and time Also the three dimensionality of space Euclidean geometry and the existence of absolute simultaneity were claimed to be necessary for the understanding of the world none of them can possibly be altered by empirical findings By moving all those concepts into a metaphysical area any form of criticism of Kantianism would be prevented Other pseudo Kantians like Ernst Cassirer or Hans Reichenbach 1920 tried to modify Kant s philosophy Subsequently Reichenbach rejected Kantianism at all and became a proponent of logical positivism A 36 B 33 B 34 C 17 C 18 C 19 Based on Henri Poincare s conventionalism philosophers such as Pierre Duhem 1914 and Hugo Dingler 1920 argued that the classical concepts of space time and geometry were and will always be the most convenient expressions in natural science therefore the concepts of relativity cannot be correct This was criticized by proponents of logical positivism such as Moritz Schlick Rudolf Carnap and Reichenbach They argued that Poincare s conventionalism could be modified to bring it into accord with relativity Although it is true that the basic assumptions of Newtonian mechanics are simpler it can only be brought into accord with modern experiments by inventing auxiliary hypotheses On the other hand relativity doesn t need such hypotheses thus from a conceptual viewpoint relativity is in fact simpler than Newtonian mechanics A 37 B 35 B 36 C 20 Some proponents of Philosophy of Life Vitalism Critical realism in German speaking countries argued that there is a fundamental difference between physical biological and psychological phenomena For example Henri Bergson 1921 who otherwise was a proponent of special relativity argued that time dilation cannot be applied to biological organisms therefore he denied the relativistic solution of the twin paradox However those claims were rejected by Paul Langevin Andre Metz and others Biological organisms consist of physical processes so there is no reason to assume that they are not subject to relativistic effects like time dilation A 38 B 37 C 21 Based on the philosophy of Fictionalism the philosopher Oskar Kraus 1921 and others claimed that the foundations of relativity were only fictitious and even self contradictory Examples were the constancy of the speed of light time dilation length contraction These effects appear to be mathematically consistent as a whole but in reality they allegedly are not true Yet this view was immediately rejected The foundations of relativity such as the equivalence principle or the relativity principle are not fictitious but based on experimental results Also effects like constancy of the speed of light and relativity of simultaneity are not contradictory but complementary to one another A 39 C 22 In the Soviet Union mostly in the 1920s philosophical criticism was expressed on the basis of dialectic materialism The theory of relativity was rejected as anti materialistic and speculative and a mechanistic worldview based on common sense was required as an alternative Similar criticisms also occurred in the People s Republic of China during the Cultural Revolution On the other hand other philosophers considered relativity as being compatible with Marxism A 40 A 41 Relativity hype and popular criticism EditAlthough Planck already in 1909 compared the changes brought about by relativity with the Copernican Revolution and although special relativity was accepted by most of the theoretical physicists and mathematicians by 1911 it was not before publication of the experimental results of the eclipse expeditions 1919 by a group around Arthur Stanley Eddington that relativity was noticed by the public Following Eddington s publication of the eclipse results Einstein was glowingly praised in the mass media and was compared to Nikolaus Copernicus Johannes Kepler and Isaac Newton which caused a popular relativity hype Relativitatsrummel as it was called by Sommerfeld Einstein and others This triggered a counter reaction of some scientists and scientific laymen who could not accept the concepts of modern physics including relativity theory and quantum mechanics The ensuing public controversy regarding the scientific status of Einstein s theory of gravity which was unprecedented was partly carried out in the press Some of the criticism was not only directed to relativity but personally at Einstein as well who some of his critics accused of being behind the promotional campaign in the German press A 42 A 3 Academic and non academic criticism Edit Some academic scientists especially experimental physicists such as the Nobel laureates Philipp Lenard and Johannes Stark as well as Ernst Gehrcke Stjepan Mohorovicic Rudolf Tomaschek and others criticized the increasing abstraction and mathematization of modern physics especially in the form of relativity theory and later quantum mechanics It was seen as a tendency to abstract theory building connected with the loss of intuitive common sense In fact relativity was the first theory in which the inadequacy of the illustrative classical physics was thought to have been demonstrated Some of Einstein s critics ignored these developments and tried to revitalize older theories such as aether drag models or emission theories see Alternative Theories However those qualitative models were never sufficiently advanced to compete with the success of the precise experimental predictions and explanatory powers of the modern theories Additionally there was also a great rivalry between experimental and theoretical physicists as regards the professorial activities and the occupation of chairs at German universities The opinions clashed at the Bad Nauheim debates in 1920 between Einstein and among others Lenard which attracted much public attention A 43 A 42 C 15 C 23 C 24 In addition there were many critics with or without physical training whose ideas were far outside the scientific mainstream These critics were mostly people who had developed their ideas long before the publication of Einstein s version of relativity and they tried to resolve in a straightforward manner some or all of the enigmas of the world Therefore Wazeck who studied some German examples gave to these free researchers the name world riddle solver Weltratselloser such as Arvid Reuterdahl Hermann Fricke or Johann Heinrich Ziegler Their views had quite different roots in monism Lebensreform or occultism Their views were typically characterized by the fact that they practically rejected the entire terminology and the primarily mathematical methods of modern science Their works were published by private publishers or in popular and non specialist journals It was significant for many free researchers especially the monists to explain all phenomena by intuitive and illustrative mechanical or electrical models which also found its expression in their defense of the aether For this reason they objected to the abstractness and inscrutability of the relativity theory which was considered a pure calculation method that cannot reveal the true reasons underlying the phenomena The free researchers often used Mechanical explanations of gravitation in which gravity is caused by some sort of aether pressure or mass pressure from a distance Such models were regarded as an illustrative alternative to the abstract mathematical theories of gravitation of both Newton and Einstein The enormous self confidence of the free researchers is noteworthy since they not only believed themselves to have solved the great riddles of the world but many also seemed to expect that they would rapidly convince the scientific community A 44 C 25 C 26 C 27 Since Einstein rarely defended himself against these attacks this task was undertaken by other relativity theoreticians who according to Hentschel formed some sort of defensive belt around Einstein Some representatives were Max von Laue Max Born etc and on popular scientific and philosophical level Hans Reichenbach Andre Metz etc who led many discussions with critics in semi popular journals and newspapers However most of these discussions failed from the start Physicists like Gehrcke some philosophers and the free researchers were so obsessed with their own ideas and prejudices that they were unable to grasp the basics of relativity consequently the participants of the discussions were talking past each other In fact the theory that was criticized by them was not relativity at all but rather a caricature of it The free researchers were mostly ignored by the scientific community but also in time respected physicists such as Lenard and Gehrcke found themselves in a position outside the scientific community However the critics didn t believe that this was due to their incorrect theories but rather due to a conspiracy of the relativistic physicists and in the 1920s and 1930s of the Jews as well which allegedly tried to put down the critics and to preserve and improve their own positions within the academic world For example Gehrcke 1920 24 held that the propagation of relativity is a product of some sort of mass suggestion Therefore he instructed a media monitoring service to collect over 5000 newspaper clippings which were related to relativity and published his findings in a book However Gehrcke s claims were rejected because the simple existence of the relativity hype says nothing about the validity of the theory and thus it cannot be used for or against relativity A 45 A 46 C 28 Afterward some critics tried to improve their positions by the formation of alliances One of them was the Academy of Nations which was founded in 1921 in the US by Robert T Browne and Arvid Reuterdahl Other members were Thomas Jefferson Jackson See and as well as Gehrcke and Mohorovicic in Germany It is unknown whether other American critics such as Charles Lane Poor Charles Francis Brush Dayton Miller were also members The alliance disappeared as early as the mid 1920s in Germany and by 1930 in the USA A 47 Chauvinism and antisemitism Edit Main article Deutsche Physik Shortly before and during World War I there appeared some nationalistically motivated criticisms of relativity and modern physics For example Pierre Duhem regarded relativity as the product of the too formal and abstract German spirit which was in conflict with the common sense Similarly popular criticism in the Soviet Union and China which partly was politically organized rejected the theory not because of factual objections but as ideologically motivated as the product of western decadence A 48 A 40 A 41 So in those countries the Germans or the Western civilization were the enemies However in Germany the Jewish ancestry of some leading relativity proponents such as Einstein and Minkowski made them targets of racially minded critics although many of Einstein s German critics did not show evidence of such motives The engineer Paul Weyland a known nationalistic agitator arranged the first public meeting against relativity in Berlin in 1919 While Lenard and Stark were also known for their nationalistic opinions they declined to participate in Weyland s rallies and Weyland s campaign eventually fizzled out due to a lack of prominent speakers Lenard and others instead responded to Einstein s challenge to his professional critics to debate his theories at the scientific conference held annually at Bad Nauheim While Einstein s critics assuming without any real justification that Einstein was behind the activities of the German press in promoting the triumph of relativity generally avoided antisemitic attacks in their earlier publications it later became clear to many observers that antisemitism did play a significant role in some of the attacks A 49 Reacting to this underlying mood Einstein himself openly speculated in a newspaper article that in addition to insufficient knowledge of theoretical physics antisemitism at least partly motivated their criticisms Some critics including Weyland reacted angrily and claimed that such accusations of antisemitism were only made to force the critics into silence However subsequently Weyland Lenard Stark and others clearly showed their antisemitic biases by beginning to combine their criticisms with racism For example Theodor Fritsch emphasized the alleged negative consequences of the Jewish spirit within relativity physics and the far right press continued this propaganda unhindered After the murder of Walther Rathenau 1922 and murder threats against Einstein he left Berlin for some time Gehrcke s book on The mass suggestion of relativity theory 1924 was not antisemitic itself but it was praised by the far right press as describing an alleged typical Jewish behavior which was also imputed to Einstein personally Philipp Lenard in 1922 spoke about the foreign spirit as the foundation of relativity and afterward he joined the Nazi party in 1924 Johannes Stark did the same in 1930 Both were proponents of the so called German Physics which only accepted scientific knowledge based on experiments and only if accessible to the senses According to Lenard 1936 this is the Aryan physics or physics by man of Nordic kind as opposed to the alleged formal dogmatic Jewish physics Additional antisemitic critics can be found in the writings of Wilhelm Muller Bruno Thuring and others For example Muller erroneously claimed that relativity was a purely Jewish affair and it would correspond to the Jewish essence etc while Thuring made comparisons between the Talmud and relativity A 50 A 51 A 52 A 42 A 53 A 54 B 38 C 29 C 30 C 31 Accusations of plagiarism and priority discussions Edit Some of Einstein s critics like Lenard Gehrcke and Reuterdahl accused him of plagiarism and questioned his priority claims to the authorship of relativity theory The thrust of such allegations was to promote more traditional alternatives to Einstein s abstract hypothetico deductive approach to physics while Einstein himself was to be personally discredited It was argued by Einstein s supporters that such personal accusations were unwarranted since the physical content and the applicability of former theories were quite different from Einstein s theory of relativity However others argued that between them Poincare and Lorentz had earlier published several of the core elements of Einstein s 1905 relativity paper including a generalized relativity principle that was intended by Poincare to apply to all physics Some examples A 55 A 56 B 39 B 40 C 32 C 33 Johann Georg von Soldner 1801 was credited for his calculation of the deflection of light in the vicinity of celestial bodies long before Einstein s prediction which was based on general relativity However Soldner s derivation has nothing to do with Einstein s since it was fully based on Newton s theory and only gave half of the value as predicted by general relativity Paul Gerber 1898 published a formula for the perihelion advance of Mercury which was formally identical to an approximate solution given by Einstein However since Einstein s formula was only an approximation the solutions are not identical In addition Gerber s derivation has no connection with General relativity and was even regarded as meaningless Woldemar Voigt 1887 derived a transformation which is very similar to the Lorentz transformation As Voigt himself acknowledged his theory was not based on electromagnetic theory but on an elastic aether model His transformation also violates the relativity principle Friedrich Hasenohrl 1904 applied the concept of electromagnetic mass and momentum which were known long before to cavity radiation and thermal radiation Yet the applicability of Einstein s Mass energy equivalence goes much further since it is derived from the relativity principle and applies to all forms of energy Menyhert Palagyi 1901 developed a philosophical space time model in which time plays the role of an imaginary fourth dimension Palagyi s model was only a reformulation of Newtonian physics and had no connection to electromagnetic theory the relativity principle or to the constancy of the speed of light Some contemporary historians of science have revived the question as to whether Einstein was possibly influenced by the ideas of Poincare who first stated the relativity principle and applied it to electrodynamics developing interpretations and modifications of Lorentz s electron theory that appear to have anticipated what is now called special relativity A 57 Another discussion concerns a possible mutual influence between Einstein and David Hilbert as regards completing the field equations of general relativity see Relativity priority dispute A Hundred Authors Against Einstein Edit A collection of various criticisms can be found in the book Hundert Autoren gegen Einstein A Hundred Authors Against Einstein published in 1931 4 It contains very short texts from 28 authors and excerpts from the publications of another 19 authors The rest consists of a list that also includes people who only for some time were opposed to relativity From among Einstein s concepts the most targeted one is space time followed by the speed of light as a constant and the relativity of simultaneity with other concepts following 5 Besides philosophic objections mostly based on Kantianism also some alleged elementary failures of the theory were included however as some commented those failures were due to the authors misunderstanding of relativity For example Hans Reichenbach wrote a report in the entertainment section of a newspaper describing the book as a magnificent collection of naive mistakes and as unintended droll literature A 58 6 Albert von Brunn interpreted the book as a pamphlet of such deplorable impotence as occurring elsewhere only in politics and a fallback into the 16th and 17th centuries and concluded it can only be hoped that German science will not again be embarrassed by such sad scribblings A 58 and Einstein said in response to the book that if he were wrong then one author would have been enough 7 8 According to Goenner the contributions to the book are a mixture of mathematical physical incompetence hubris and the feelings of the critics of being suppressed by contemporary physicists advocating the new theory The compilation of the authors show Goenner continues that this was not a reaction within the physics community only one physicist Karl Strehl and three mathematicians Jean Marie Le Roux Emanuel Lasker and Hjalmar Mellin were present but a reaction of an inadequately educated academic citizenship which did not know what to do with relativity As regards the average age of the authors 57 were substantially older than Einstein one third was around the same age and only two persons were substantially younger A 59 Two authors Reuterdahl von Mitis were antisemitic and four others were possibly connected to the Nazi movement On the other hand no antisemitic expression can be found in the book and it also included contributions of some authors of Jewish ancestry Salomo Friedlander Ludwig Goldschmidt Hans Israel Emanuel Lasker Oskar Kraus Menyhert Palagyi A 59 A 60 C 34 Status of criticism EditSee also Tests of special relativity and Tests of general relativity The theory of relativity is considered to be self consistent is consistent with many experimental results and serves as the basis of many successful theories like quantum electrodynamics Therefore fundamental criticism like that of Herbert Dingle Louis Essen Petr Beckmann Maurice Allais and Tom van Flandern has not been taken seriously by the scientific community and due to the lack of quality of many critical publications found in the process of peer review they were rarely accepted for publication in reputable scientific journals Just as in the 1920s most critical works are published in small publication houses alternative journals like Apeiron or Galilean Electrodynamics or private websites A 4 A 5 Consequently where criticism of relativity has been dealt with by the scientific community it has mostly been in historical studies A 1 A 2 A 3 However this does not mean that there is no further development in modern physics The progress of technology over time has led to extremely precise ways of testing the predictions of relativity and so far it has successfully passed all tests such as in particle accelerators to test special relativity and by astronomical observations to test general relativity In addition in the theoretical field there is continuing research intended to unite general relativity and quantum theory between which a fundamental incompatibility still remains 9 The most promising models are string theory and loop quantum gravity Some variations of those models also predict violations of Lorentz invariance on a very small scale B 41 B 42 B 43 See also EditAlternatives to general relativity Fringe science History of special relativityReferences Edit Pruzan Peter 2016 Research Methodology The Aims Practices and Ethics of Science illustrated ed Springer p 81 ISBN 978 3 319 27167 5 Extract of page 81 Brecher K 1977 Is the speed of light 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theory of relativity Chicago London The Open court publishing company De Sitter Willem 1913 A proof of the constancy of the velocity of light Proceedings of the Royal Netherlands Academy of Arts and Sciences 15 2 1297 1298 Bibcode 1913KNAB 15 1297D De Sitter Willem 1916a On the relativity of rotation in Einstein s theory Roy Amst Proc 17 1 527 532 permanent dead link De Sitter Willem 1916b On the relativity of inertia Remarks concerning Einstein s latest hypothesis Roy Amst Proc 17 2 1217 1225 Bibcode 1917KNAB 19 1217D permanent dead link Dirac Paul 1951 Is there an Aether PDF Nature 168 4282 906 907 Bibcode 1951Natur 168 906D doi 10 1038 168906a0 S2CID 4288946 Archived from the original PDF on 17 December 2008 Retrieved 31 January 2011 Einstein Albert 1905a Zur Elektrodynamik bewegter Korper PDF Annalen der Physik 322 10 891 921 Bibcode 1905AnP 322 891E doi 10 1002 andp 19053221004 hdl 10915 2786 See also English translation Einstein Albert 1908 Uber das Relativitatsprinzip und die aus demselben gezogenen Folgerungen PDF Jahrbuch der Radioaktivitat und Elektronik 4 411 462 Bibcode 1908JRE 4 411E Einstein Albert 1912 Relativitat und Gravitation Erwiderung auf eine Bemerkung von M Abraham PDF Annalen der Physik 343 10 1059 1064 Bibcode 1912AnP 343 1059E doi 10 1002 andp 19123431014 S2CID 120162895 Einstein Albert 1916 Die Grundlage der allgemeinen Relativitatstheorie PDF Annalen der Physik 49 7 769 782 Bibcode 1916AnP 354 769E doi 10 1002 andp 19163540702 hdl 2027 wu 89059241638 Einstein A 1920a Meine Antwort Uber die anti relativitatstheoretische G m b H Berliner Tageblatt 402 Archived from the original on 14 December 2009 Einstein Albert 1920b Ether and the Theory of Relativity London Methuen pp 3 24 Einstein Albert 1924 Uber den Ather Verhandlungen der Schweizerischen Naturforschenden Gesellschaft 105 85 93 Einstein Albert Rosen Nathan 1936 Two Body Problem in General Relativity Physical Review 49 5 404 405 Bibcode 1936PhRv 49 404E doi 10 1103 PhysRev 49 404 2 Fox J G 1965 Evidence Against Emission Theories American Journal of Physics 33 1 1 17 Bibcode 1965AmJPh 33 1F doi 10 1119 1 1971219 Joos Georg 1959 Lehrbuch der theoretischen Physik Frankfurt am Main Akademische Verlagsgesellschaft Frankfurt p 448 Kretschmann Erich 1917 Uber den physikalischen Sinn der Relativitatspostulate A Einsteins neue und seine ursprungliche Relativitatstheorie Annalen der Physik 358 16 575 614 Bibcode 1918AnP 358 575K doi 10 1002 andp 19183581602 Langevin P 1911 Translated by J B Sykes in 1973 The evolution of space and time Scientia X 31 54 Langevin Paul 1921 Sur la theorie de relativite et l experience de M Sagnac Comptes Rendus 173 831 834 Langevin Paul 1937 Sur l experience de Sagnac Comptes Rendus 205 304 306 Laue Max von 1911 Zur Diskussion uber den starren Korper in der Relativitatstheorie On the Discussion Concerning Rigid Bodies in the Theory of Relativity Physikalische Zeitschrift 12 85 87 Laue Max von 1917 Die Fortpflanzungsgeschwindigkeit der Gravitation Bemerkungen zur gleichnamigen Abhandlung von P Gerber Annalen der Physik 358 11 214 216 Bibcode 1917AnP 358 214V doi 10 1002 andp 19173581103 Laue Max von 1921a Die Relativitatstheorie Vol 1 Braunschweig Friedr Vieweg amp Sohn Laue Max von 1921b Erwiderung auf Hrn Lenards Vorbemerkungen zur Soldnerschen Arbeit von 1801 Annalen der Physik 371 20 283 284 Bibcode 1921AnP 371 283L doi 10 1002 andp 19213712005 Liberati Stefano Maccione Luca 2009 Lorentz Violation Motivation and new constraints Annual Review of Nuclear and Particle Science 59 1 245 267 arXiv 0906 0681 Bibcode 2009ARNPS 59 245L doi 10 1146 annurev nucl 010909 083640 S2CID 7495956 Lorentz Hendrik Antoon 1904 Electromagnetic phenomena in a system moving with any velocity smaller than that of light Proceedings of the Royal Netherlands Academy of Arts and Sciences 6 809 831 Bibcode 1903KNAB 6 809L Mattingly David 2005 Modern Tests of Lorentz Invariance Living Reviews in Relativity 8 5 5 arXiv gr qc 0502097 Bibcode 2005LRR 8 5M doi 10 12942 lrr 2005 5 PMC 5253993 PMID 28163649 Metz Andre 1923 La Relativite Paris Chiron Michelson A A Gale Henry G 1925 The Effect of the Earth s Rotation on the Velocity of Light II Astrophysical Journal 61 140 Bibcode 1925ApJ 61 140M doi 10 1086 142879 Planck Max 1906a Das Prinzip der Relativitat und die Grundgleichungen der Mechanik The Principle of Relativity and the Fundamental Equations of Mechanics Verhandlungen Deutsche Physikalische Gesellschaft 8 136 141 Planck Max 1906b Die Kaufmannschen Messungen der Ablenkbarkeit der b Strahlen in ihrer Bedeutung fur die Dynamik der Elektronen The Measurements of Kaufmann on the Deflectability of b Rays in their Importance for the Dynamics of the Electrons Physikalische Zeitschrift 7 753 761 Planck Max 1925 Vom Relativen zum Absoluten Naturwissenschaften 13 3 52 59 Bibcode 1925NW 13 53P doi 10 1007 BF01559357 S2CID 19895936 Poincare Henri 1906 Sur la dynamique de l electron On the Dynamics of the Electron Rendiconti del Circolo Matematico di Palermo 21 129 176 Bibcode 1906RCMP 21 129P doi 10 1007 BF03013466 hdl 2027 uiug 30112063899089 S2CID 120211823 Reichenbach Hans 1965 First published in German 1920 The theory of relativity and a priori knowledge Berkeley University of California Press Reichenbach Hans 1969 First published in German 1924 Axiomatization of the theory of relativity Berkeley University of California Press Roberts Thomas J An Explanation of Dayton Miller s Anomalous Ether Drift Result 2006 arXiv physics 0608238 Schlick Moritz 1921 Space and time in contemporary physics 3 ed New York Oxford University Press Smoot G F 2006 Nobel lecture Cosmic Microwave Background Radiation Anisotropies Their Discovery and Utilization Sommerfeld Arnold 1907 Ein Einwand gegen die Relativtheorie der Elektrodynamik und seine Beseitigung An Objection Against the Theory of Relativity and its Removal Physikalische Zeitschrift 8 23 841 842 Sommerfeld Arnold 1914 Uber die Fortpflanzung des Lichtes in dispergierenden Medien Annalen der Physik 349 10 177 202 Bibcode 1914AnP 349 177S doi 10 1002 andp 19143491002 Usenet Physics FAQ is FTL travel or communication Possible Will Clifford M 2006 The Confrontation between General Relativity and Experiment Living Reviews in Relativity 9 3 3 arXiv gr qc 0510072 Bibcode 2006LRR 9 3W doi 10 12942 lrr 2006 3 PMC 5256066 PMID 28179873 Critical works Edit Abraham 1904 Kaufmann 1906 Miller 1933 Ehrenfest 1909 Abraham 1912 Poincare 1904 Dingle 1972 Lodge 1925 Michelson 1927 Prokhovnik 1963 Ives 1951 Lenard 1921a Silberstein 1921a Ritz 1908 a b Lenard Einstein Gehrcke Weyl 1920 Silberstein 1936 Natorp 1910 Linke 1921 Friedlaender 1932 Dingler 1922 Bergson 1921 Kraus 1921 Gehrcke 1924a Mohorovicic 1923 Fricke 1919 Ziegler 1920 Reuterdahl 1921 Gehrcke 1924b Lenard 1936 Stark Muller 1941 Thuring 1941 Gehrcke 1916 Lenard 1921b Israel et al 1931 Abraham Max 1904 Die Grundhypothesen der Elektronentheorie The Fundamental Hypotheses of the Theory of Electrons Physikalische Zeitschrift 5 576 579 Abraham Max Max 1912 Relativitat und Gravitation Erwiderung auf eine Bemerkung des Herrn A Einstein Annalen der Physik 343 10 1056 1058 Bibcode 1912AnP 343 1056A doi 10 1002 andp 19123431013 Bergson Henri 1923 First edition 1921 Duree et simultaneite A propos de la theorie d Einstein second ed Saint Germain Felix Alcan Dingle Herbert 1972 Science at the Crossroads London Martin Brian amp O Keeffe ISBN 978 0 85616 060 8 Dingler Hugo 1922 Relativitatstheorie und Okonomieprinzip Leipzig S Hirzel Ehrenfest Paul 1909 Gleichformige Rotation starrer Korper und Relativitatstheorie Uniform Rotation of Rigid Bodies and the Theory of Relativity Physikalische Zeitschrift 10 918 Bibcode 1909PhyZ 10 918E Essen Louis 1971 The Special Theory of Relativity A Critical Analysis Oxford Oxford University Press ISBN 978 0 19 851921 8 Fricke Hermann 1919 Der Fehler in Einsteins Relativitatstheorie Wolfenbuttel Heckner Friedlaender Salomo 2005 1932 Kant gegen Einstein In Geerken Hartmut Thiel Detlef eds Gesammelte Schriften Books on Demand ISBN 978 3 8370 0052 8 Gehrcke Ernst 1916 Zur Kritik und Geschichte der neueren Gravitationstheorien Annalen der Physik 356 17 119 124 Bibcode 1916AnP 356 119G doi 10 1002 andp 19163561704 Gehrcke Ernst 1924a Kritik der Relativitatstheorie Gesammelte Schriften uber absolute und relative Bewegung Berlin Meusser Gehrcke Ernst 1924b Die Massensuggestion der Relativitatstheorie Kulturhistorisch psychologische Dokumente Berlin Meuser Ives Herbert E 1951 Revisions of the Lorentz transformation Proceedings of the American Philosophical Society 95 2 125 131 Kaufmann Walter 1906 Uber die Konstitution des Elektrons On the Constitution of the Electron Annalen der Physik 324 3 487 553 Bibcode 1906AnP 324 487K doi 10 1002 andp 19063240303 Kraus Oskar 1921 Fiktion und Hypothese in der Einsteinschen Relativitatstheorie Erkenntnistheoretische Betrachtungen Annalen der Philosophie 2 3 335 396 doi 10 1007 BF02903489 S2CID 169705566 Lenard Philipp 1921a 1920 Uber Relativitatsprinzip Ather Gravitation 3 enlarged ed Leipzig Hirzel Lenard Einstein Gehrcke Weyl 1920 The Bad Nauheim Debate Physikalische Zeitschrift 21 666 668 Lenard Philipp Hrsg 1921b Vorbemerkung zu Soldners Uber die Ablenkung eines Lichtstrahls von seiner geradlinigen Bewegung durch die Attraktion eines Weltkorpers an welchem er nahe vorbeigeht Annalen der Physik 370 15 593 604 Bibcode 1921AnP 370 593S doi 10 1002 andp 19213701503 Lenard Philipp 1936 Deutsche Physik Vol 1 Munchen J F Lehmann Linke Paul F 1921 Relativitatstheorie und Relativismus Betrachtungen uber Relativitatstheorie Logik und Phanomenologie Annalen der Philosophie 2 3 397 438 doi 10 1007 BF02903490 S2CID 127977740 Lodge Oliver 2003 1925 Ether and Reality Whitefish Kessinger ISBN 978 0 7661 7865 6 Michelson Albert A 1927 Studies in Optics Chicago University Press p 155 Miller Dayton C 1933 The Ether Drift Experiment and the Determination of the Absolute Motion of the Earth Reviews of Modern Physics 5 3 203 242 Bibcode 1933RvMP 5 203M doi 10 1103 RevModPhys 5 203 S2CID 4119615 Mohorovicic Stjepan 1923 Die Einsteinsche Relativitatstheorie und ihr mathematischer physikalischer und philosophischer Charakter Berlin de Gruyter Natorp Paul 1910 Das Relativitatsprinzip etc Die logischen Grundlagen der exakten Wissenschaften Leipzig amp Berlin B G Teubner pp 392 404 Poincare Henri 1913 1904 The Principles of Mathematical Physics The Value of Science Chap 7 9 New York Science Press pp 297 320 This paper is only partly to be considered as critical since the question after the validity of the relativity principle remained undecided It was Poincare himself who solved many problems in 1905 Prokhovnik Simon Jacques 1963 The Case for an Aether The British Journal for the Philosophy of Science 14 55 195 207 doi 10 1093 bjps XIV 55 195 S2CID 122050844 Reuterdahl Arvid 1920 Scientific theism versus materialism The space time potential New York Devin Adair Ritz Walter 1908 Recherches critiques sur l Electrodynamique Generale Annales de Chimie et de Physique 13 145 275 Bibcode 1908AChPh 13 145R Siehe auch englische Ubersetzung Silberstein Ludwik 1920 The Recent Eclipse Results and Stokes Planck s AEther Philosophical Magazine 6 39 230 162 171 Silberstein Ludwik 1936 Two Centers Solution of the Gravitational Field Equations and the Need for a Reformed Theory of Matter Physical Review 49 3 268 270 Bibcode 1936PhRv 49 268S doi 10 1103 PhysRev 49 268 Stark Johannes Muller Wilhelm 1941 Judische und Deutsche Physik Vortrage an der Universitat Munchen Thuring Bruno 1941 Albert Einsteins Umsturzversuch der Physik und seine inneren Moglichkeiten und Ursachen Forschungen zur Judenfrage 4 134 162 Ziegler Johann Heinrich 1857 1936 1920 Das Ding an sich und das Ende der sog Relativitatstheorie Zurich Weltformel Verlag External links EditThe Newspaper clippings and works collected by Gehrcke and Reuterdahl form an important basis for historic research on the criticism of relativity The Ernst Gehrcke Papers Over 2700 newspaper articles collected by Gehrcke digitized at the MPIWG Arvid Reuterdahl Papers digizied by the University of St Thomas Libraries which are online accessible Retrieved from https en wikipedia org w index php title Criticism of the theory of relativity amp oldid 1123138264, wikipedia, wiki, book, books, library,

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