In his book, Relativity: The Special and General Theory, Einstein claimed that the clocks in a gravitational field, as well as those located on a rotating disc, run slower solely due to the gravitational potential, no matter how much acceleration they undergo. He then replaces potential per unit mass with velocity square $(r^2\omega^2)$ of a clock located at a radius $r$ on the disc:
... If we represent the difference of potential of the centrifugal force between the position of the clock and the centre of the disc by $\phi$ , i.e. the work, considered negatively, which must be performed on the unit of mass against the centrifugal force in order to transport it from the position of the clock on the rotating disc to the centre of the disc, then we have
$$\phi=\frac{\omega^2r^2}{2}$$
... Now, as judged from the disc, the latter is in a gravitational field of potential $\phi$, hence the result we have obtained will hold quite generally for gravitational fields...
... Now $\phi=-K\frac{M}{r}$, where $K$ is Newton’s constant of gravitation, and $M$ is the mass of the heavenly body.
Assume that we have a massive spherical planet with a hollow core. At the first approximation, the gravitational acceleration is zero everywhere inside the hollow core as predicted by classical mechanics. However, the gravitational potential is not zero in the core. Now, consider two observers, one has been trapped and is floating inside the core of this massive planet, and the other floating inside a massless shell in an interstellar space away from the gravitation of the planet, yet at rest with respect to the planet. (A Schwarzschild observer)
If these observers hold similar light clocks, GR predicts that time dilates for the clock within the planet's core because of non-zero gravitational potential compared to the clock held by the observer inside the massless shell. Nonetheless, do you think that this result is logically tenable, or is it compatible with EEP (Einstein equivalence principle)?
Indeed, using EEP, each of these observers can by no means detect if he is inside a massive planet or a massless shell floating in interstellar space. That is, observers' feelings are the same, both undergoing similar weightlessness, and all experiments have similar outcomes from the viewpoint of these observers.
According to the fact that the relative velocity of these observers is zero, it is logically anticipated that their clocks run at the same rate but this is not the case! Where is the problem?
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