gravitational potential in Newton's theory. A glance at (90) and (90a) shows that the actually do play the role of the intensity of the gravitational field. These quantities do not have a tensor character.
Equations (90) express the influence of inertia and gravitation upon the material particle. The unity of inertia and gravitation is formally expressed by the fact that the whole left-hand side of (90) has the character of a tensor (with respect to any transformation of co-ordinates), but the two terms taken separately do not have tensor character, so that, in analogy with Newton's equations, the first term would be regarded as the expression for inertia, and the second as the expression for the gravitational force.
We must next attempt to find the laws of the gravitational field. For this purpose, Poisson's equation,
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of the Newtonian theory must serve as a model. This equation has its foundation in the idea that the gravitational field arises from the density of ponderable matter. It must also be so in the general theory of relativity. But our investigations of the special theory of relativity have shown that in place of the scalar density of matter we have the tensor of energy per unit volume. In the latter is included not only the tensor of the energy of ponderable matter, but also that of the electromagnetic energy. We have seen, indeed, that in a more complete analysis the energy tensor can be regarded only as a provisional means of representing
