From this follows
|
|
(123) |
If the universe is quasi-Euclidean, and its radius of curvature therefore infinite, then would vanish. But it is improbable that the mean density of matter in the universe is actually zero; this is our third argument against the assumption that the universe is quasi-Euclidean. Nor does it seem possible that our hypothetical pressure can vanish; the physical nature of this pressure can be appreciated only after we have a better theoretical knowledge of the electromagnetic field. According to the second of equations (123) the radius, , of the universe is determined in terms of the total mass, , of matter, by the equation
|
|
(124) |
The complete dependence of the geometrical upon the physical properties becomes clearly apparent by means of this equation.
Thus we may present the following arguments against the conception of a space-infinite, and for the conception of a space-bounded, universe:—
1. From the standpoint of the theory of relativity, the condition for a closed surface is very much simpler than the corresponding boundary condition at infinity of the quasi-Euclidean structure of the universe.
