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NASA found the point in the universe where nothing exists.


The bubble of nothing. The diameter of that bubble is about 300 light-years is the place where is the lowest known energy level. The density of radiation and other fields are lowest as possible. That area is interesting. Because there some researchers hope that they could see the fourth dimension. 

The thing that separates the third dimension from the fourth dimension is the energy level. At which a particle loses its ability to interact with other 3D particles. That great nothing can just uncover the Higgs field. And it can answer the question does the proton split? That could uncover the possibility of the formation of iron stars. 

As I wrote many times the energy roof in the third dimension is the energy floor of the fourth dimension. In this area, the energy floor of the fourth dimension is extremely low. And researchers could think that they could see tachyon interaction. Theoretically, the tachyon cannot come out from the fourth dimension because the energy floor or energy that transfers to the tachyon at the point where it should start to interact with material pushes it back to the fourth dimension.  




The bubble of nothing is the place that is as close to the universe in its last times as possible. 


The low energy level makes it possible. That tachyon will enter into the third dimension. At that moment. There is no energy anymore that can push those particles back to the fourth dimension. So in a very old universe, tachyons can also travel in that low energy and a very cold place. Maybe Iron stars are the last stars that are creating energy. That thing requires that the proton is not splitting. If a proton splits the last energy source would be splitting protons. The splitting neutrons are the things that are also capable of energy sources. 

The bubble of nothing is the area that is as close to the time at the end of the universe as possible. The energy level in the old universe is very low if we compare it with the universe where we live. The material and gravitation interact similar way as they interact now. So near the last stars is similar plasma bubbles. That is around the Sun and other stars. But the universe or space is lower energy than it's today. 

The universe's density is lower and that means the difference between material density near stars and interstellar space is steeper than it's now. So when photons or electrons are traveling between stars. They are traveling faster than they travel today. And when those photons or electrons hit the plasma bubble they will slow their speed sending Cherenkov radiation. The energy roof is lower and there is a possibility that the tachyons can slip in that very cold universe where is only a couple of red dwarfs, black dwarfs, and maybe iron stars. 


https://en.wikipedia.org/wiki/Iron_star

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