Can dark matter be the quantum-size version of the gravastars?
Dark matter is a mystery. It is suggested that dark matter particles are so-called quantum-size black holes. Einstein’s models suggest that any objects in the universe. They can turn into black holes. This thing happens. When outside radiation presses electrons into an atom’s core. Then the radiation must “only” melt the particles in the atom’s core. Into one entirety. This entirety is called singularity. There is a suggestion that all particles involve a quantum-sized black hole. And the thing. What we see as a particle is the halo of the quantum-size black hole.
Then to the hypothetical. gravastars. If we think that the quantum-sized black holes exist. We can think. That. The quantum-sized versions of gravistars or gravitational vacuum stars. Also existed. The gravastar. It could solve many problems in fundamental physics. The gravastar explains dark energy. That. If the shell of a gravastar, or a quantum-sized gravastar, breaks. That lets the gravitational field travel into that gravitational vacuum. That causes the effect. That is similar to a vacuum bomb. That vacuum. It can collect and focus energy. Into the middle of it.
But some other new models suggest that some black holes are actually gravastars. So-called hollow singularities. There, the entire mass of the object is in that object’s core. The hypothetical gravitational vacuum stars are also dense objects. But their matter is like a ball around the area. Its gravity affects symmetrically from its edge. And that forms the gravitational vacuum in the middle of that object.
So there is a possibility. The microlensing forms a situation. Their energy focuses straight into the center of the atom’s core. That thing can cause the photonic nuclear reaction. That can cause the neutron decay. Or it could transform a proton in the atom’s nucleus into an anti-proton. That can cause. A nuclear reaction that throws the mass of an entire atom into a ball-shaped structure. And that thing means that the dark matter. It could be like a quantum-sized version of the gravastar.
“A diagram comparing the structure of a classical black hole with a gravastar.” (Wikipedia, Gravastar)
And then to the gamma-rays from the Sagittarius A*.
Strange gamma-ray bursts from near the Milky Way’s center. They are things that are suggested to be from dark matter. But then we can imagine situation that the high-power radiation from the Sgr A*(Sagittarius A*), the supermassive black hole in the center of the Milky Way can form that gamma-ray. The idea is that the extremely high-energy radiation comes from the black hole’s accretion disk, pushing electrons away from the atomic nucleus. When that radiation hits electrons. And free protons that form when hydrogen atoms release their electrons.
Proton has two up and one down quark. It is a possibility. The energy impulse can turn an up quark into a down quark. And if that happens in the proton, that baryon turns into a neutron. The neutron involves two down quarks and one up quark. The down quark is a higher-energy particle than the up quark. And neutron decay. It means that the down quark turns back into an up quark. Also, a high-energy photon. It can cause a photo-nuclear reaction in an atom’s core. The photo-nuclear reaction forms in a situation. That atom transforms into a very high-excitation state. That state can cause a situation. The neutrons start to decay in the atom’s core.
Those high-power radiation quanta can transform those protons.
Another up quark. Into down quarks that transform those protons into neutrons. Because the energy level in the material disk around the Sgr A* changes. Those changes can cause decay in just-born neutrons. So that down quark transforms back to an up quark. And that reaction. It releases a W-boson and electrons. The decay produces one proton, two electrons, and one electron antineutrino. So, it's possible that the electron antineutrino hits the electron neutrino. And that should release some kind of radiation. But the radiation that comes from that acceleration disk pushes those electrons away. When those high-energy electrons are far enough from the Sgr A* they realease their extra energy as gamma-ray quanta.
There are three possible sources. For those gamma-rays.
1) Still hypothetical dark matter particles.
2) Nautrons that can form in the high-energy radiation. Or the radiation from Sgr A* can destroy atom nucleus and release those neutrons. Then, neutron decay sends electrons. Or, one proton, two electrons. And one electron antineutrino.
3) Electrons that high-energy radiation releases from their orbitals. When those electrons travel away from Sgr A*. And the energy transfer to those electrons ends. That thing makes them send gamma-rays.
Some effects near supermassive black holes are not actually very exotic. Those things can happen more often than anywhere else. This means that the mysterious gamma rays can open the path. To find out the mystery of dark matter. The mystery is. Are dark matter particles? If they exist, a source for those gamma-ray bursts. There is a question. Does dark matter even have a particle form? And if those hypothetical particles are the source of those gamma-rays.
That radiation. It can form when those particles impact. Or it can be the transformation radiation. That means the black hole radiation. It can transform particles into dark matter. The idea is that. The spin of the particle turns into 1 or higher. That thing means that the particle can turn invisible. As long as it binds energy inside it. So it's possible. That. The high-energy radiation. It can turn a particle invisible. And maybe that transformation. It can be seen as gamma-ray flashes.
The thing. That dark matter causes a gravitational effect. It means that the dark matter should surround any black hole in the universe. Or actually, every gravity center will pack dark matter around it. But the problem is this. Nobody has seen dark matter yet. So, the dark matter halo. The matter. The matter that surrounds supermassive black holes should be large and dense enough. The astronomers could observe that strange matter. The dark matter could lens light. But that thing is very hard to separate from the gravitational lensing.
The problem with that thing. It is the high-energy material disk around the black hole. The high-energy, extremely bright material disk. Covers the dark matter below it. In the same way, a traffic light can cover dust and snow below its brightness. And maybe those very dense objects. They can deliver information about the strange gravitational effect. Known as dark matter.
https://www.space.com/astronomy/dark-universe/a-mysterious-gamma-ray-stream-comes-from-the-milky-ways-center-could-dark-matter-have-something-to-do-with-it
https://www.space.com/astronomy/dark-universe/supermassive-black-holes-may-be-surrounded-by-dark-matter-clusters-new-echo-map-technique-suggests
https://en.wikipedia.org/wiki/Dark_energy
https://en.wikipedia.org/wiki/Dark_matter
https://en.wikipedia.org/wiki/Free_neutron_decay
https://en.wikipedia.org/wiki/Gravastar
https://en.wikipedia.org/wiki/Neutrino
https://en.wikipedia.org/wiki/Neutron
https://en.wikipedia.org/wiki/Neutron_emission
https://en.wikipedia.org/wiki/Proton
https://en.wikipedia.org/wiki/Standard_Model
No comments:
Post a Comment
Note: Only a member of this blog may post a comment.