the proper time of the material particle. As opposed to is therefore an invariant, and is practically equivalent to for motions whose velocity is small compared to that of light. Hence we see that
|
(39) |
has, just as the , the character of a vector; we shall designate as the four-dimensional vector (in brief, 4-vector) of velocity. Its components satisfy, by (38), the condition
|
(40) |
We see that this 4-vector, whose components in the ordinary notation are
|
(41) |
is the only 4-vector which can be formed from the velocity components of the material particle which are defined in three dimensions by
|
We therefore see that
|
(42) |
must be that 4-vector which is to be equated to the 4-vector of momentum and energy whose existence we have proved above. By equating the components, we obtain, in three-dimensional notation,