Could the answer. For the dark energy mystery. Be. In some process of particle evaporation, which is previously unknown? And could that thing be the quark annihilation?
Cosmic voids and material evaporation are interesting things. When we think about comic voids and conditions inside them. There. Quantum fields are weaker than in other places in the universe. This causes a material evaporation effect. And the question is, can this effect release as much energy as annihilation? When a particle starts to evaporate. An atom loses its electron shell. That gives the atom core room to expand, and then the bonds between protons and neutrons will break.
In that process, energy is stored in the bonds between protons and neutrons. This energy release could form the extremely small WARP bubble around the atom shell. In that process, the evaporation reaction. It can be faster than predicted. When those bonds between protons and neutrons release their energy, that causes an effect. They also release energy into quarks that form protons and neutrons. This causes an energy impulse that pushes those quarks farther from each other.
Released. This releases free energy in the system. Then the neutrons and protons start to decay. Or they release their quarks. This can happen. When a weak quantum field lets quantum fields around quarks expand. This causes that. The distance between those quarks starts to increase.
“Graphic of quarks annihilating (left green lines), producing a photon (middle line), and producing two muons (right magenta lines). Scientists detected these muons to gain insight into the quark asymmetry of the proton. Image credit: Paul Reimer, Argonne National Laboratory”. (University of Michigan, Study finds unexpected antimatter asymmetry in the proton)
Sooner or later, the distance between quarks is so long that the bonds between them start to break. The neutron decay is confirmed. Two down and one up quarks form a neutron. This means energy travels to the up quark. And this effect causes neutron decay.
Proton is more complicated. Its main structure is two up and one down quark. The energy travels to those up quarks more smoothly than in a neutron. But there are also particle-antiparticle pairs in proton. When the proton’s quantum field starts to expand, that causes an effect in which those particles and anti-particles touch each other. This effect rips a proton. In pieces. This requires that the quantum field around the proton expands as much as it allows those particle-antiparticle pairs to touch each other. Normally, the structure of a proton keeps antimatter and its mirror particles away from each other. But when a proton expands, that allows those particle-antiparticle pairs to annihilate.
In that case, those bonds between those three quarks also release energy that is stored in them. In this process, the situation is similar to that in proton-antiproton annihilation. In that process. The reaction releases energy that is stored in those bonds. And finally, quarks and electrons turn into wave motion.
So, when we think that there is too much energy in the universe, we must ask, could that energy form in this type of reaction? When we think about material evaporation. And its relationship with dark energy, we must realize one thing. When reseachers make their calculations, they should know and handle every stage of those reactions. In cosmic voids, the speed of light is higher than outside it. This means all particles travel faster than they do outside the cosmic void. When they hit the edge of the void, they release that energy into those quantum fields.
https://www.anl.gov/argonne-scientific-publications/pub/164087
https://news.umich.edu/study-finds-unexpected-antimatter-asymmetry-in-the-proton/
https://en.wikipedia.org/wiki/Dark_energy
https://en.wikipedia.org/wiki/Dark_matter
https://en.wikipedia.org/wiki/Neutron
https://en.wikipedia.org/wiki/Proton
https://en.wikipedia.org/wiki/Standard_Model
https://en.wikipedia.org/wiki/Void_(astronomy)
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