Biography:Paul Gerber

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Short description: German physicist

Paul Gerber (1854 Berlin, Germany – 13 August 1909 Freiburg im Breisgau, Germany ) was a German physics teacher. He studied in Berlin from 1872-1875. In 1877 he became a teacher at the Realgymnasium (high school) in Stargard in Pommern. Gerber is known for his controversial work on the speed of gravity and the perihelion shift of Mercury's orbit.

Gravitation

Basic concept

Based on the electrodynamic laws of Wilhelm Eduard Weber, Carl Friedrich Gauß, and Bernhard Riemann, between 1870-1900 many scientists tried to combine gravitation with a finite propagation speed and tried to derive the correct value for the perihelion shift of Mercury's orbit.[B 1][B 2] In 1890 Maurice Lévy succeeded in doing so by combining the laws of Weber and Riemann, whereby the speed of gravity is equal to the speed of light in his theory.[A 1] However, because the basic laws of Weber and others were wrong (for example, Weber's law was superseded by Maxwell's equations), those hypotheses were rejected.

A variation of those superseded theories (albeit not directly based on Weber's theory) was the one of Gerber, which he developed in 1898 and 1902.[A 2] By assuming a finite speed of gravity, he developed the following expression for the gravitational potential:

[math]\displaystyle{ V=\frac {\mu} {r \left(1- \frac {1} {c} \frac {dr} {dt} \right)^2} }[/math]

Using the binomial theorem to second order it follows:

[math]\displaystyle{ V=\frac {\mu} {r} \left[1+\frac {2} {c} \frac {dr} {dt} + \frac {3} {c^2} \left(\frac {dr} {dt} \right)^2 \right] }[/math]

According to Gerber, the relation of the speed of gravity (c) and the perihelion shift (Ψ) is:

[math]\displaystyle{ c^2=\frac {6\pi\mu} {a(1-\epsilon^2)\Psi} }[/math]

where

[math]\displaystyle{ \mu=\frac {4\pi^2a^3} {\tau^2} }[/math], ε = Eccentricity, a = Semi-major axis, τ = Orbital period.

So Gerber was able to calculate a speed of gravity of ca. 305 000 km/s, slightly more than the speed of light.[B 3][B 4]

Controversy

Gerber's formula gives for the perihelion shift:

[math]\displaystyle{ \Psi=24\pi^3\frac {a^2} {\tau^2 c^2(1-\epsilon^2)} }[/math]

It was noted by the Einstein- and relativity critic Ernst Gehrcke in 1916,[A 3] that this formula is mathematically identical to Albert Einstein's formula (1915) for general relativity.[A 4]

[math]\displaystyle{ \epsilon=24\pi^3\frac {a^2} {T^2c^2(1-e^2)} }[/math], where e = Eccentricity, a = Semi-major axis, T = Orbital period.

So Gehrcke initiated a reprint of Gerber's 1902-paper in the Annalen der Physik in 1917, where he questioned the priority of Einstein and tried to prove a possible plagiarism by him.[A 5] However, according to Albrecht Fölsing,[B 5] Klaus Hentschel[B 6] and Roseveare,[B 7] those claims were rejected, because soon after Gerber's paper was reprinted, scientists like Hugo von Seeliger,[A 6] Max von Laue[A 7] published some papers, where it was claimed that Gerber's theory is inconsistent and his formula is not the consequence of his premises. And Einstein wrote in 1920:[A 8]

In the recent past, Roseveare argued that Gerber's derivation is unclear, however, he claimed to have found the way by which Gerber possibly found his result[B 7] (although Roseveare's derivation was criticized as well[web 1]). More importantly, Roseveare showed that Gerber's theory is in conflict with experience: the value for the deflection of light in the gravitational field of the sun is too high in Gerber's theory, and if the relativistic mass is considered, also Gerber's prediction for the perihelion advance is wrong.

References

Primary sources
  • Einstein, A. (1915). "Erklärung der Perihelbewegung des Merkur aus der allgemeinen Relativitätstheorie". Sitzungsberichte der Preussischen Akademie der Wissenschaften (2): 831–839. 
  • Gerber, P. (1898). "Die räumliche und zeitliche Ausbreitung der Gravitation". Zeitschrift für Mathematik und Physik 43: 93–104. 
Secondary sources
  • {{Cite journal
|author  = Zenneck, J.
|year    = 1901
|title   = Gravitation
|journal = Encyklopädie der mathematischen Wissenschaften mit Einschluss ihrer Anwendungen
|volume  = 5
|issue = 1
|pages   = 25–67
|url     = http://dz-srv1.sub.uni-goettingen.de/sub/digbib/loader?did=D189514
Endnotes for primary sources Endnotes for secondary sources
  1. Levy 1890
  2. Gerber 1898, 1902
  3. Gehrcke (1916)
  4. Einstein (1915 and (1916), 822
  5. Gerber 1917
  6. Seeliger (1917)
  7. Laue (1917, 1920)
  8. Einstein 1920
  1. Zenneck 1901, 46ff
  2. Oppenheim 1920, 153ff
  3. Zenneck 1901, 49ff
  4. Oppenheim 1920, 156f
  5. Fölsing 1993, Chap. 5
  6. Hentschel 1990, pp.150ff.
  7. 7.0 7.1 Roseveare 1982, Chap. 6
Notes
  1. German: Herr Gehrcke will glauben machen, daß die Perihelbewegung des Merkur auch ohne Relativitätstheorie zu erklären sei. Es gibt da zwei Möglichkeiten. Entweder man erfindet besondere interplanetare Massen. [...] Oder aber man beruft sich auf eine Arbeit von Gerber, der die richtige Formel für die Perihelbewegung des Merkur bereits vor mir angegeben hat. Aber die Fachleute sind nicht nur darüber einig, daß Gerbers Ableitung durch und durch unrichtig ist, sondern die Formel ist als Konsequenz der von Gerber an die Spitze gestellten Annahmen überhaupt nicht zu gewinnen. Herrn Gerbers Arbeit ist daher völlig wertlos, ein mißglückter und irreparabler theoretischer Versuch. Ich konstatiere, daß die allgemeine Relativitätstheorie die erste wirkliche Erklärung für die Perihelbewegung des Merkur geliefert hat. Ich habe die Gerbersche Arbeit ursprünglich schon deshalb nicht erwähnt, weil ich sie nicht kannte, als ich meine Arbeit über die Perihelbewegung des Merkur schrieb; ich hätte aber auch keinen Anlaß gehabt, sie zu erwähnen, wenn ich von ihr Kenntnis gehabt hätte.

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