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Anonymous at Wed, 19 Jun 2024 06:10:12 UTC No. 16242255

If the warping of spacetime can exceed the speed of light, then this means that gravitational forces can travel faster than light through warped spacetime.

All reference frames experience local spacetime. This includes singularities. Singularity F experiences an instant in spacetime, moving from T0 to T1. F's past self still exists at T0. We will call this singularity P. The gravitational effect of F exceeds the speed of light and travels through warped spacetime and warps P's spacetime near infinitely and instantly.

The gravitational force of P's singularity cannot over come the gravitational force of F and P explodes in all directions instantly. Spacetime for P instantly expands proportional to the gravitational influence of F. This is what we observe as the first instant of the big bang.

Gravitational strength is inversely proportional to the square of the distance. After the expansion of P's spacetime, the strength of F instantly weakens proportional to the distance to P. We can now think of P as being at T0.000...1 and F still being at T1.

To put this into a different perspective: F is a black hole representing a future singularity. P is a white hole representing a past singularity. Due to the gravitational effects of F, a wormhole opens between P and F. Now the distance between P and F are the length of the wormhole. This wormhole is our flat universe as we presently observe it.

As matter travels through the wormhole, it approaches the future singularity F at T1. As the matter approaches T1 the gravitational influence of F increases. This is what we observe as dark energy or cosmic acceleration. This implies that our universe is within the event horizon of the future singularity. No matter what direction we travel or how fast or slow we travel, we can never escape approaching the future singularity at T1.

When all matter from the past singularity P arrives at T1, what happens?