|
This file is an HTML copy of Willem de Sitter's article in
Proceedings of the Section of Sciences - Koninklijke Academie
van Wetenschappen -- te Amsterdam, 16, 395 (1913).
395
End of previous article deleted.
Astronomy. -- "On the constancy of
the velocity of light". By
Prof. W. de Sitter
In my communication to the meeting of February of this year (see these
Proceedings, Vol 15, page 1297) I pointed out that the existence of
spectroscopic doubles whose motion obeys the laws of Kepler, is
incompatible with the theory of Ritz, while in agreement with that
of Lorentz.
Since then Messr. P. Guthnick1 and E. Freundlich2
have brought forward the hypothesis that the velocity of light might
depend on the velocity of the source in a manner differing from the simple
addition postulated by the theory of Ritz. The most simple hypothesis
would be
v = c + xu,
where v is the velocity of light emitted by a source having the
velocity u. The problem then is no longer to decide whether
x = 0 or x = 1, intermediate values being excluded, but to
assign an upper limit to x.
We have then, using the notations of my former paper
If the true orbit is a circle, then the equation (1) becomes:
If x is very small we find for the equation (2) the following
approximate expression
__________
1 Astronomische Kriterien für die Unabhängigkeit der
Dortplanzungsgeschwindigkeit des Lichtes von der Bewegung der
Lichtquelle, Astr. Nachr. 4670
(195, 265).
2 Zur Frage der Konstanz der Lichtgeschwindigkeit, Physik.
Zeitschr. 14, 835).
[*] 
represents the distance from a double star to an observer.
396
where naturally u, u, c,
,
{tau} and T must all
be expressed in the same units (km. and sec.) The observed velocities will
thus show a spurious excentricity, of the amount
This unites with the true excentricity and cannot be separated from it by
observations.
Now it is easy to derive an upper limit for x. Take a well known
star like
 Aurigae.
The observations give
As the largest values which are still compatible with the observations
we can take
p < 0".05, or
> 65 lightyears,
e < 0.015,
We find then
x < 0.002.
Quite possibly other stars will give smaller values of x. The
smallest values, of course, are found from the stars having the smallest
parallaxes. Unfortunately the parallax of most spectroscopic doubles is
still unknown, and it is thus impossible to give numerical values. We
can however assume as certain that for the majority of these stars a
value would be found which is still smaller than that given above.
Postscript. During the discussions at the meeting the remark was
made (by Prof. Korteweg) that the star
Aurigae
might have a true
excentricity of such amount as exactly to cancel the spurious excentricity
produced by the motion. This is, of course, entirely correct. If this
true excentricity 1 were e = 0.90 we should find
x = 0.12, [taking again p = 0".05 and using the same
approximate formula as above, though this is not correct for such large
excentricities]. Thus if we knew only this one star, we should have to
adopt as upper limit for x this value 0.12. There are however a
considerable number of stars with large values of uo,
whose observed excentricity is very small or zero. Several of these
certainly have very small parallaxes. It would evidently be absurd to
assume that all of these possessed exactly that true excentricity and
position of the periastron which would cancel the apparent excentricity
for an observer on our earth.
__________
1
For Aurigae
a large excentricity is particularly improbable on account of the
presumably large dimensions of both components as compared with their
mutual distance.
Assistance was provided by the Interlibrary Loan Services at
Mississippi State University's Mitchell Memorial Library and
The Smithsonian Institution Libraries in obtaining a copy of
the original "Proceedings" article.
__________
Installed 01 Jun 2006.
_________
Shade Tree Physics
| |
|