Page:Eddington A. Space Time and Gravitation. 1920.djvu/158

It was formerly supposed that the mass of a particle was a number attached to the particle, expressing an intrinsic property, which remained unaltered in all its vicissitudes. If ${\displaystyle m}$ is this number, and ${\displaystyle u}$ the velocity of the particle, the momentum is ${\displaystyle mu}$; and it is through this relation, coupled with the law of conservation of momentum that the mass ${\displaystyle m}$ was defined. Let us take for example two particles of masses ${\displaystyle m_{1}=2}$ and ${\displaystyle m_{2}=3}$, moving in the same straight line. In the space-time diagram for an observer ${\displaystyle S}$ the velocity of the first particle will be represented by a direction ${\displaystyle OA}$ (Fig. 19). The first particle moves through

a space ${\displaystyle MA}$ in unit time, so that ${\displaystyle MA}$ is equal to its velocity referred to the observer ${\displaystyle S}$. Prolonging the line ${\displaystyle OA}$ to meet the second time-partition, ${\displaystyle NB}$ is equal to the velocity multiplied by the mass 2; thus the horizontal distance ${\displaystyle NB}$ represents the momentum. Similarly, starting from ${\displaystyle B}$ and drawing ${\displaystyle BC}$ in the direction of the velocity of ${\displaystyle m_{2}}$, prolonged through three time-partitions, the horizontal progress from ${\displaystyle B}$ represents the momentum of the second particle. The length ${\displaystyle PC}$ then represents the total momentum of the system of two particles.

Suppose that some change of their velocities occurs, not involving any transference of momentum from outside, e.g. a collision. Since the total momentum ${\displaystyle PC}$ is unaltered, a similar