Boson, fermion, and dense proton stars.

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 Boson, fermion, and dense proton stars. 

Conventional stars are forming mainly protons, which are fermions but also consist of Helium^4 nuclei, which are bosons. Scientists have introduced the possibility that between black holes and neutron stars would be the large group of massive objects like quark stars, fermion stars boson stars.

But sometimes I have thought, could the protons form similar type entirety with the neutron or fermion-electrons? So are super dense proton stars possible? The super-dense proton stars are theoretical objects what are formed similarly to the neutron stars.

Those super-exotic stars are formed of protons, but they are not producing energy internally. They would be a little bit different than electron stars, and that's why I´m using the terms fermion star when I mean electron star and the proton star means the super dense proton star. But there are no straight observations about those things. 

There are hypothetically at least two types of fermion stars. Electron stars and cold proton stars, which are formed of protons, but are not producing energy anymore. In that case, the protons are forming a similar entirety as neutrons form in neutron stars.

Boson stars can be formed by  W+, W-, Higgs bosons or helium, or lead-208 atoms. Those stars would be more common than Fermion stars. But yet we don't have a single prove that those objects have existed. If we want to find that kind of object, we should know what the gravity waves, what is leaving from the colliding of those objects are looking like.

So at the first, we should find the colliding of black holes, and then analyze the gravity waves of that collimation. Then the researchers should find the collimation, which sends a different type of gravity waves. The different gravity waves and other particles can uncover that the objects, that are colliding are formed by the collimation of objects, which have different masses than black holes and neutron stars. So there is the possibility that those colliding stars are the fermion or boson stars. And then analyzing that data would take time. 

The colliding of black holes can solve the big mysteries like the existence of boson and even fermion stars. The fermion stars could be formed by electrons and the requirement of the existence of those electron or proton stars is that the masses of those particles are different, and that thing causes that the particles that have the same polarity can connect to one entirety. 

Proton stars are similar thing to fermion and neutron stars. They are formed by the protons and the birth mechanism of those stars is similar. The thing that makes fermion and proton stars interesting is that those things have only one pole. And that things drive ions and electrons in one direction. 

Science is one black-and-white thing. Even if fermion or boson stars could be found, that would not mean that every black hole in the universe is a fermion or boson stars. There might be all of those objects in the universe. But there is one thing that causes interesting ideas. 

The reason why those particles are not impacting with fermion or proton stars is that every single particle at the surface of those objects would be superposition and the quantum entanglement makes them acting like little rolls. That means that fermion and proton stars can travel in the universe because the jet what the material that would travel to the pole would be acting as the rocket jet. 

A similar effect can cause that the neutron star would theoretically start to travel in the universe. If the neutron star would face the large cloud of positive ions or ions with the same polarity, that causes that the particles would travel to the opposite pole of the neutron star, and then that material can work as the jet, what moves neutron star through the universe. 

The possibility of the existence of the fermion stars is very low, but maybe they are existing. The connection between the particles that have the same polarity is extremely difficult, and that means that fermion stars can exist in extremely thin energy areas. 

Sometimes I have thought that could the possibility to find fermion stars be lower than finding the intelligent lifeform. The boson stars are different and more common than the hypothetical fermion stars. Or we can say that the boson stars are also invisible to the human eye. And some people are playing with the thought, that maybe every stellar black hole is boson stars. So maybe only supermassive black holes are real black holes, and the rest of the black holes are the boson stars. 

The thing we should do for confirming that thing is to travel to every stellar-size black hole, and then we should make a research about that thing. But the fact is that both of those hypothetical stars, fermion (electron) stars, and the boson stars are quantum entanglement. They would rotate extremely fast near those stars and drive the photons in one direction. 

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

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

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

https://www.thenationalnews.com/uae/science/how-the-collision-of-two-black-holes-may-solve-one-of-the-universe-s-biggest-mysteries-1.1179509

Image: https://www.thenationalnews.com/uae/science/how-the-collision-of-two-black-holes-may-solve-one-of-the-universe-s-biggest-mysteries-1.1179509