“Dark matter’s nature has long eluded scientists, but new theoretical and experimental advances are pointing to an unexpected candidate: superheavy, electrically charged gravitinos. (Artist’s concept). Credit: SciTechDaily.com”(ScitechDaily, The Hunt for Dark Matter Has a New, Surprising Target)
“Superheavy charged gravitinos may be the long-sought answer to dark matter.” (ScitechDaily, The Hunt for Dark Matter Has a New, Surprising Target)
“Dark Matter remains one of the biggest mysteries in fundamental physics. Many theoretical proposals (axions, WIMPs) and 40 years of extensive experimental search have not explained what Dark Matter is. Several years ago, a theory that seeks to unify particle physics and gravity introduced a radically different possibility: superheavy, electrically charged gravitinos as Dark Matter candidates.”(ScitechDaily, The Hunt for Dark Matter Has a New, Surprising Target)
The shape of dark matter is a mystery. But the fact is that dark matter is predicted to form particles called weakly interacting massive particles, WIMPs. The new theory suggests that the WIMPs are gravitons, which are on a higher energy level than they should be. The problem is that nobody has seen the gravito. The theoretical gravitation transportation particle. Then we can ask the question: Why is dark matter invisible? The answer can be that those particles spin so fast that they push energy waves around them. And that means there is no reflection about those particles.
In that model, the graviton is the electromagnetic shadow of some spinaxle particles that moves the wave. In some other models, the graviton is a miniature black hole that could exist in all particles. But there are more exotic models about the shape of the graviton and dark matter. In this model, dark matter forms when a neutrino goes into another neutrino. In that model, two internal neutrinos start to spin oppositely.
That means an internal particle that can be something other than a neutrino spins in the opposite direction to the particle that forms the shell of this double particle. The macro-effect of this thing can be found in magnetars. If the neutron star’s shell spins oppositely to its core, that forms the most powerful magnetic field in the universe. So what if another neutrino traps another neutrino inside it, and those internal neutrinos start to spin in opposite directions? That thing means that the double particle can form an extremely strong quantum gravity field.
“New simulations of neutron star mergers reveal that the mixing and changing of tiny particles called neutrinos impacts how the merger unfolds, including the composition and structure of the merger remnant as well as the resulting emissions. This image depicts the density of neutrinos within the remnant as varying textures, and the colors represent energy densities of different neutrino flavors. Credit: David Radice research group / Penn State” (ScitechDaily, First-Ever Simulations Reveal Ghost Particles Shapeshifting in Violent Neutron Star Mergers)
“New simulations show that neutrino flavor transformations change both the composition and the signals left behind after neutron star collisions.” (ScitechDaily, First-Ever Simulations Reveal Ghost Particles Shapeshifting in Violent Neutron Star Mergers)
“When two neutron stars collide and merge, the result is one of the most energetic events in the universe. These cataclysms generate multiple kinds of signals that can be detected from Earth.” (ScitechDaily, First-Ever Simulations Reveal Ghost Particles Shapeshifting in Violent Neutron Star Mergers)
When we think about neutron star collisions, there is a possibility that high-energy neutrinos are affected in that process. Normally, neutrinos are weakly interacting particles. Those particles can travel through even entire planets without interaction. In neutron star collisions, very many neutrinos. And the environment where those neutrinos interact with other particles is much denser than in the case of planets. Neutrinos will interact with quarks and other particles more often than in the normal universe.
When neutrinos take an extremely high energy level. And when the energy level around them decreases, those neutrinos can realease that energy. When that extremely thick neutrino cloud releases its extra energy, that energy can rip a neutron star into pieces.
That thing can explain the hypothetical case where a neutrino could trap another neutrino. Or maybe the particle that traps the neutrino inside it could be a quark or an electron. When neutrino and other elementary particles travels at very high speeds, and their mutual speed is almost the same. The energy level around those particles is extremely high, and that can push neutrinos. into each other. Or that energy can push a quark inside another quark. That can form particles that are unknown to us.
https://scitechdaily.com/first-ever-simulations-reveal-ghost-particles-shapeshifting-in-violent-neutron-star-mergers/
https://scitechdaily.com/the-hunt-for-dark-matter-has-a-new-surprising-target/
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