According also to the general theory of relativity, which differs of course from the theory of Newton, a small variation from the Newton-Kepler motion of a planet in its orbit should take place, and in such away, that the angle described by the radius sun-planet between one perhelion and the next should exceed that corresponding to one complete revolution by an amount given by

eq. 41:  file eq41.gif

(N.B. —­ One complete revolution corresponds to the angle 2p in the absolute angular measure customary in physics, and the above expression giver the amount by which the radius sun-planet exceeds this angle during the interval between one perihelion and the next.) In this expression a represents the major semi-axis of the ellipse, e its eccentricity, c the velocity of light, and T the period of revolution of the planet.  Our result may also be stated as follows :  According to the general theory of relativity, the major axis of the ellipse rotates round the sun in the same sense as the orbital motion of the planet.  Theory requires that this rotation should amount to 43 seconds of arc per century for the planet Mercury, but for the other Planets of our solar system its magnitude should be so small that it would necessarily escape detection. *

In point of fact, astronomers have found that the theory of Newton does not suffice to calculate the observed motion of Mercury with an exactness corresponding to that of the delicacy of observation attainable at the present time.  After taking account of all the disturbing influences exerted on Mercury by the remaining planets, it was found (Leverrier:  1859; and Newcomb:  1895) that an unexplained perihelial movement of the orbit of Mercury remained over, the amount of which does not differ sensibly from the above mentioned +43 seconds of arc per century.  The uncertainty of the empirical result amounts to a few seconds only.

 (b) Deflection of Light by a Gravitational Field

In Section 22 it has been already mentioned that according to the general theory of relativity, a ray of light will experience a curvature of its path when passing through a gravitational field, this curvature being similar to that experienced by the path of a body which is projected through a gravitational field.  As a result of this theory, we should expect that a ray of light which is passing close to a heavenly body would be deviated towards the latter.  For a ray of light which passes the sun at a distance of D sun-radii from its centre, the angle of deflection (a) should amount to

eq. 42:  file eq42.gif

It may be added that, according to the theory, half of Figure 05 this deflection is produced by the Newtonian field of attraction of the sun, and the other half by the geometrical modification (” curvature “) of space caused by the sun.